Methods and systems for delivering an implant using a planetary gear actuation assembly

ABSTRACT

A system for delivering an implant including a handle, a trigger, and an actuation assembly. The actuation assembly can be configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member upon return of the trigger from the second position to the first position.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 14/932,900, filed on Nov. 4, 2015, now U.S. Pat. No. 10,154,920, which claims priority to U.S. Provisional Application No. 62/075,059, filed on Nov. 4, 2014, the entire contents of which is incorporated herein by reference.

BACKGROUND Field of Disclosed Subject Matter

The disclosed subject matter is directed to systems and methods for delivering one or more medical devices, for example an implant, and more specifically, a braided implant. The braided implant, for example a stent or scaffold, can be disposed within a delivery system having an actuation assembly configured to deliver the braided implant using a reciprocating motion.

Description of Related Art

Conventional self-expanding stent delivery systems can include a handle housing portion and an elongated shaft, wherein the stent is disposed within a delivery portion at the distal end of the shaft. To deploy the stent, an outer sheath is retracted relative to the stent, whereby the stent is released from its delivery configuration. In certain systems, an inner member having a pushing mechanism disposed proximate to its distal end can be used to push the stent from the outer sheath, while the outer sheath is retracted.

However, there remains a need for a system and method for more accurately delivering an implant using a relatively simple motion and ease of use.

SUMMARY

The purpose and advantages of the disclosed subject matter will be set forth in and apparent from the description that follows, as well as will be learned by practice of the disclosed subject matter. Additional advantages of the disclosed subject matter will be realized and attained by the methods and systems particularly pointed out in the written description and claims hereof, as well as from the appended drawings.

To achieve these and other advantages and in accordance with the purpose of the disclosed subject matter, as embodied and broadly described, the disclosed subject matter is directed to systems and methods for delivering an implant. For example, an implant can be disposed within a distal end portion of an outer tubular member of the system and positioned to be engaged by a distal end portion of an inner shaft member of the system when the inner shaft member is moved distally relative to the outer tubular member. The inner shaft member can be disposed within the outer tubular member and movable distally and proximally relative to the outer tubular member. The system for delivering an implant can include a handle, a trigger, operatively coupled to the handle, and an actuation assembly operatively coupled to the trigger, the inner shaft member, and the outer tubular member.

The actuation assembly as disclosed herein is a planetary gear type assembly. Particularly, the actuation assembly can include a planet carrier, at least one planet gear operatively coupled to the planet carrier, a sun gear shaft operatively engaged with the planet gear, a ring gear operatively engaged with the planet gear, a first clutch driver configured to limit the sun gear shaft to uni-directional rotational motion, and a second clutch driver configured to uni-directionally lock the sun gear shaft and the planet carrier. The actuation assembly disclosed herein is configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and further the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position.

The second clutch driver can be configured to uni-directionally lock the sun gear shaft and the planet carrier such that the sun gear shaft, planet carrier and the ring gear have a 1:1 ratio of rotation during deployment of the trigger from the first position to the second position. The actuation assembly can also include a clutch release operatively coupled to the second clutch driver and configured to prevent the second clutch driver from uni-directionally locking the sun gear shaft and the planet carrier when the clutch release is engaged by a stop. The stop can be disposed on the handle, and the stop can engage the clutch release when the actuation assembly has moved proximally a distance (z) along the handle. For example, the clutch release can include a saw-tooth portion and the stop can include a resilient abutment portion, the resilient abutment portion of the stop can engage the saw-tooth portion of the clutch release when the actuation assembly has moved proximally a distance (z) along the handle.

The first clutch driver can be configured to limit the sun gear shaft to uni-directional motion such that the sun gear shaft does not rotate during return of the trigger from the second position to the first position and the planetary gear rotates about the sun gear shaft. The sun gear shaft can be functionally coupled to the outer tubular member such that upon deployment of the trigger from the first position to the second position the sun gear shaft rotates and thereby causes the outer tubular member to move proximally relative to the handle.

As embodied herein, the actuation assembly can include a shuttle frame having the planet carrier, planet gear, sun gear shaft, ring gear, first clutch driver and second clutch driver disposed thereon. The shuttle frame can be fixedly coupled to the outer tubular member. The sun gear shaft can be functionally coupled to the handle such that upon deployment of the trigger from the first position to the second position the sun gear shaft rotates and the shuttle frame moves proximally a distance relative to the handle. Additionally, the actuation assembly can include an intermediate gear functionally disposed on the shuttle frame between the sun gear shaft and the handle, and operatively engaged with the sun gear shaft.

Furthermore, the actuation assembly can include a ratchet rack fixedly coupled to the inner shaft member and disposed on the shuttle frame. The ratchet rack can be operatively engaged with the planet carrier. The ratchet rack can be operatively engaged with the ring gear.

The actuation assembly can be functionally coupled to the trigger by a driving rack. The driving rack can be operatively engaged with the ring gear and the driving rack can be supported by the handle. The driving rack can be operatively engaged with the planet carrier and the driving rack can be supported by the shuttle frame.

As further embodied herein, the actuation assembly can include at least one pin configured to engage at least one pin track disposed within the handle to thereby guide the shuttle frame along the handle. The at least one pin can include a first pin disposed through an axis of an intermediate gear functionally disposed on the shuttle frame between the sun gear shaft and the handle. The at least one pin can include a second and third pin, each of the second and third pin disposed through the shuttle frame. The at least one pin can include a fourth pin disposed through an axis of the sun gear shaft. The actuation assembly further can include a plate disposed on the shuttle frame.

A sheath gondola can also be provided, disposed between the outer tubular member and the sun gear shaft, wherein the sheath gondola is functionally coupled to the sun gear shaft by a first tension element. The actuation assembly can include a ratchet gondola disposed between the inner tubular member and the ring gear, wherein the ratchet gondola is functionally coupled to the ring gear by a second tension element.

The sun gear shaft can include a sun gear portion, a sheath pinion, and a clutch engagement portion. The planet carrier can include a circumferential pinion, a clutch component, and at least one pin. The ring gear can include a circumferential pinion and a ring gear portion. The first clutch driver and the second clutch driver can each include a sun gear shaft engagement portion and a clutch portion.

As embodied herein, the actuation assembly can be functionally coupled to the trigger by a driving rack. The trigger can include a slide having an engagement surface to be engaged by the user. The slide can be fixedly coupled to the driving rack.

The trigger of the disclosed subject matter can be functionally connected to the driving rack by a gear train. The gear train can include a trigger gear sector, a trigger pinion operatively meshed with the trigger gear sector, a slide pinion operatively coupled to the trigger pinion, and a slid rack disposed on a slide coupled to the driving rack and operatively meshed with the trigger pinion. The driving rack can be fixedly coupled to the slide. The driving rack can be detachably coupled to the slide.

Alternatively, or additionally, the trigger can be functionally connected to the driving rack by one or more link elements. For example, a plurality of link elements can be provided. The plurality of link elements can include a first linear link coupled to the trigger at a first joint, a second linear link coupled to the slide at a second joint, and a triangle link coupled to the first linear link at a third joint and the second linear link at a fourth joint. The triangle link can be coupled to the handle at a fifth joint, and the trigger can be coupled to the handle at a sixth joint. Each of the first, second, third, fourth, fifth, and sixth joints can be pivot joints. The third joint, fourth joint, and fifth joint thus can define a triangle. Upon deployment of the trigger from the first position to the second position and return of the trigger from the second position to the first position, the third joint can trace a non-linear path. Alternatively, the trigger can be functionally connected to the driving rack by a trigger pulley system.

Furthermore, the system can include a ratchet mechanism functionally coupled to the trigger. The ratchet mechanism can include a first state configured to allow the trigger to move toward the second position and prohibit motion toward the first position. The ratchet mechanism can include a second state configured to allow the trigger to move toward the first position and prohibit motion toward the second position. As embodied herein, the ratchet mechanism can include a first pawl and a trigger ratchet rack configured to engage the pawl to permit unidirectional motion of the slide. The pawl can include a first state wherein the pawl engages the trigger ratchet rack to permit unidirectional motion of the slide in a first direction. The pawl can include a second state wherein the pawl engages the trigger ratchet rack to permit unidirectional motion of the slide in a second direction. The pawl can be configured to switch from the first state to the second state as the trigger approaches the second position from the first position. The pawl can be configured to switch from the second state to the first state as the trigger approaches the first position from the second position. The pawl can be configured to be disengaged with the trigger ratchet rack by urging the pawl away from the trigger ratchet rack. The pawl can be biased toward engagement with the trigger ratchet rack.

Additionally, the ratchet mechanism can include a second pawl having a first state wherein the second pawl engages the ratchet rack to permit unidirectional motion of the slide in a second direction. The first and second pawl can each have a second state wherein the first and second pawl do not engage the trigger ratchet rack, particularly when the other pawl is in engagement. In this manner when the first pawl is in the first state the second pawl can be in the second state and when the second pawl is in the first state the first pawl can be in the second state. The ratchet mechanism can also include a ratchet trip coupled to the first and second pawls. As the trigger approaches the second position from the first position the ratchet trip can cause the first pawl to switch from the first state to the second state and the ratchet trip can cause the second pawl to switch from the second state to the first state. As the trigger approaches the first position from the second position the ratchet trip can cause the first pawl to switch from the second state to the first state and the ratchet trip can cause the second pawl to switch from the first state to the second state.

As disclosed herein, the trigger can be coupled to a spring such that energy is stored in the spring upon deployment of the trigger from the first position to the second position, and the energy stored in the spring causes the trigger to return from the second position to the first position. The system can include a spring support coupled to the trigger and a base and configured to engage the spring such that energy is stored in the spring when the trigger is in the first position.

As further disclosed herein, a system for delivering an implant is provided. The system can include a handle, as well as a trigger, an outer tubular member, and an inner shaft member, each operatively coupled to the handle. An implant can be provided with the system as a kit or separately. The trigger can be movable between a first position and a second position. The handle can further have an actuation assembly operatively coupled to the trigger. The outer tubular member can include a proximal end portion and a distal end portion, wherein the outer member is operatively coupled to the actuation assembly and movable in a proximal direction relative to the handle. The inner shaft member can include a proximal end portion and a distal end portion. The inner shaft member is disposed within the outer tubular member and operatively coupled to the actuation assembly. The inner shaft member can be movable distally and proximally relative to the outer tubular member. The implant can be disposed within the distal end portion of the outer tubular member and positioned to be engaged by the distal end portion of the inner shaft member when the inner shaft member is moved distally relative to the outer tubular member. The actuation assembly disclosed herein is configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from the first position to the second position, and further wherein the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position.

The distance (y) minus the distance (x) can substantially equal the distance (d). Upon deployment of the trigger from the first position to the second position and return of the trigger from the second position to the first position, a net displacement of the inner shaft member relative to the outer tubular member can be zero. The braided implant can have a length, the length of the braided implant can be less than the distance (x). Repeatedly deploying the trigger from the first position to the second position and returning the trigger from the second position to the first position can cause the inner shaft member to urge the braided implant from the outer tubular member. The actuation assembly can be configured to displace the outer tubular member a distance (d) in the proximal direction relative to the handle upon deployment of the trigger from the first position to the second position. The handle can be configured to fit within a hand of a user and upon repeated deployment of the trigger from the first position to the second position and return of the trigger from the second position to the first position the actuation assembly can be configured to move from a position within the handle distal of the user's hand to a position within the handle proximal of the user's hand. The actuation assembly can include a planetary gear system.

According to another embodiment of the disclosed subject matter, a system for delivering an implant is provided. The system can include a handle, a trigger operatively coupled to the handle, and an actuation means configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and further wherein the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and are intended to provide further explanation of the disclosed subject matter claimed.

The accompanying drawings, which are incorporated in and constitute part of this specification, are included to illustrate and provide a further understanding of the disclosed subject matter. Together with the description, the drawings serve to explain the principles of the disclosed subject matter.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a perspective view of an exemplary embodiment of a delivery system in accordance with the disclosed subject matter.

FIG. 2 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 1.

FIG. 3 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 1.

FIG. 4 provides a top perspective view of selected elements of the actuation assembly of the delivery system of FIG. 1.

FIGS. 5A-5D provide perspective FIG. 5A, right—FIG. 5B, left FIG. 5C, and front FIG. 5D views of the sun gear shaft of the delivery system of FIG. 1.

FIGS. 6A-6D provide perspective FIG. 6A, right FIG. 6B, left FIG. 6C, and front FIG. 6D views of the planet carrier of the delivery system of FIG. 1.

FIGS. 7A-7D provide perspective FIG. 7A, right FIG. 7B, left FIG. 7C, and front FIG. 7D views of the ring gear of the delivery system of FIG. 1.

FIGS. 8A-8D provide perspective FIG. 8A, right FIG. 8B, left FIG. 8C, and front FIG. 8D views of the first clutch driver of the delivery system of FIG. 1.

FIGS. 9A-9D provide perspective FIG. 9A, right FIG. 9B, left FIG. 9C, and front FIG. 9D views of the shuttle frame of the delivery system of FIG. 1.

FIGS. 10A-10D provide perspective FIG. 10A, right FIG. 10B, left FIG. 10C, and front FIG. 10D views of the intermediate gear of the delivery system of FIG. 1.

FIGS. 11A-11D provide perspective FIG. 11A, right FIG. 11B, left FIG. 11C, and front FIG. 11D views of the clutch release of the delivery system of FIG. 1.

FIG. 12 is a perspective view illustrating the relationship between the planet carrier and the planet gears of the delivery system of FIG. 1.

FIGS. 13A-13D are various views depicting the relationship between the sun gear shaft and the planet gears of the delivery system of FIG. 1.

FIGS. 14A-14D are various views depicting the relationship between the ring gear and the planet gears of the delivery system of FIG. 1.

FIGS. 15A-15D are various views depicting relationship between the sun gear shaft and the first and second clutch drivers of the delivery system of FIG. 1.

FIG. 16 is a perspective view illustrating the relationship between the sun gear shaft, the planet carrier, and the second clutch driver of the delivery system of FIG. 1.

FIG. 17 is a perspective view illustrating the relationship between the sun gear shaft, the first clutch driver, and the shuttle frame of the delivery system of FIG. 1.

FIG. 18 is a side view illustrating the relationship between the sun gear shaft, intermediate gear, and handle of the delivery system of FIG. 1.

FIG. 19 is a perspective view illustrating the relationship between the shuttle frame and the ratchet member of the delivery system of FIG. 1.

FIG. 20 is a perspective view illustrating the relationship between the ring gear and the ratchet member of the delivery system of FIG. 1.

FIG. 21 is an enlarged view showing the relationship between the handle, pins, and plate of the delivery system of FIG. 1.

FIGS. 22A-22C are various views showing the relationship between the shuttle frame, driving rack, and planet carrier of the delivery system of FIG. 1.

FIG. 23 is a side view showing the relationship between the clutch release and the second clutch driver of the delivery system of FIG. 1.

FIG. 24 is a perspective view of another exemplary embodiment of a delivery system in accordance with the disclosed subject matter.

FIG. 25 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 24.

FIG. 26 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 24.

FIGS. 27A-27D provide perspective FIG. 27A, right FIG. 27B, left FIG. 27C, and front FIG. 27D views of the sun gear shaft of the delivery system of FIG. 24.

FIGS. 28A-28D provide perspective FIG. 28A, right FIG. 28B, left FIG. 28C, and front FIG. 28D views of the planet carrier of the delivery system of FIG. 24.

FIGS. 29A-29D provide perspective FIG. 29A, right FIG. 29B, left FIG. 29C, and front FIG. 29D views of the ring gear of the delivery system of FIG. 24.

FIGS. 30A-30D provide perspective FIG. 30A, right FIG. 30B, left FIG. 30C, and front FIG. 30D views of the first clutch driver of the delivery system of FIG. 24.

FIGS. 31A-31D provide perspective FIG. 31A, right FIG. 31B, left FIG. 31C, and front FIG. 31D views of the shuttle frame of the delivery system of FIG. 24.

FIGS. 32A-32D provide perspective FIG. 32A, right FIG. 32B, left FIG. 32C, and front FIG. 32D views of the intermediate gear of the delivery system of FIG. 24.

FIGS. 33A-33D provide perspective FIG. 33A, right FIG. 33B, left FIG. 33C, and front FIG. 33D views of the clutch release of the delivery system of FIG. 24.

FIGS. 34A-34C are various views showing the relationship between the shuttle frame, driving rack, and ring gear of the delivery system of FIG. 24.

FIG. 35 is a perspective view showing the relationship between the planet carrier and the ratchet member of the delivery system of FIG. 24.

FIG. 36 is a perspective view of a yet another exemplary embodiment of delivery system in accordance with the disclosed subject matter.

FIG. 37 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 36.

FIG. 38 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 36.

FIGS. 39A-39D provide perspective FIG. 39A, right FIG. 39B, left FIG. 39C, and front FIG. 39D views of the sun gear shaft of the delivery system of FIG. 36.

FIGS. 40A-40D provide perspective FIG. 40A, right FIG. 40B, left FIG. 40C, and front FIG. 40D views of the planet carrier of the delivery system of FIG. 36.

FIGS. 41A-41D provide perspective FIG. 41A, right FIG. 41B, left FIG. 41C, and front FIG. 41D views of the ring gear of the delivery system of FIG. 36.

FIGS. 42A-42D provide perspective FIG. 42A, right FIG. 42B, left FIG. 42C, and front FIG. 42D views of the first clutch driver of the delivery system of FIG. 36.

FIGS. 43A-43D provide perspective FIG. 43A, right FIG. 43B, left FIG. 43C, and front FIG. 43D views of the shuttle frame of the delivery system of FIG. 36.

FIGS. 44A-44D provide perspective FIG. 44A, right FIG. 44B, left FIG. 44C, and front FIG. 44D views of the intermediate gear of the delivery system of FIG. 36.

FIGS. 45A-45D provide perspective FIG. 45A, right FIG. 45B, left FIG. 45C, and front FIG. 45D views of the clutch release of the delivery system of FIG. 36.

FIG. 46 is an exploded view of a further exemplary embodiment of a delivery system in accordance with the disclosed subject matter.

FIGS. 47A-47D provide perspective FIG. 47A, right FIG. 47B, left FIG. 47C, and front FIG. 47D views of the sun gear shaft of the delivery system of FIG. 46.

FIGS. 48A-48D provide perspective FIG. 48A, right FIG. 48B, left FIG. 48C, and front FIG. 48D views of the planet carrier of the delivery system of FIG. 46.

FIGS. 49A-49D provide perspective FIG. 49A, right FIG. 49B, left FIG. 49C, and front FIG. 49D views of the ring gear of the delivery system of FIG. 46.

FIGS. 50A-50D provide perspective FIG. 50A, right FIG. 50B, left FIG. 50C, and front FIG. 50D views of the first clutch driver of the delivery system of FIG. 46.

FIGS. 51A-51D provide perspective FIG. 51A, right FIG. 51B, left FIG. 51C, and front FIG. 51D views of the shuttle frame of the delivery system of FIG. 46.

FIG. 52 is a perspective view of another exemplary embodiment of a delivery system in accordance with the disclosed subject matter.

FIG. 53 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 52.

FIG. 54 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 52.

FIGS. 55A-55D provide perspective FIG. 55A, right FIG. 55B, left FIG. 55C, and front FIG. 55D views of the sun gear shaft of the delivery system of FIG. 52.

FIGS. 56A-56D provide perspective FIG. 56A, right FIG. 56B, left FIG. 56C, and front FIG. 56D views of the planet carrier of the delivery system of FIG. 52.

FIGS. 57A-57D provide perspective FIG. 57A, right FIG. 57B, left FIG. 57C, and front FIG. 57D views of the ring gear of the delivery system of FIG. 52.

FIGS. 58A-58D provide perspective FIG. 58A, right FIG. 58B, left FIG. 58C, and front FIG. 58D views of the first clutch driver of the delivery system of FIG. 52.

FIGS. 59A-59D provide perspective FIG. 59A, right FIG. 59B, left FIG. 59C, and front FIG. 59D views of the shuttle frame of the delivery system of FIG. 52.

FIGS. 60A-60D provide perspective FIG. 60A, right FIG. 60B, left FIG. 60C, and front FIG. 60D views of the intermediate gear of the delivery system of FIG. 52.

FIGS. 61A-61D provide perspective FIG. 61A, right FIG. 61B, left FIG. 61C, and front FIG. 61D views of the clutch release of the delivery system of FIG. 52.

FIG. 62 is a perspective view of a further exemplary embodiment of a delivery system in accordance with the disclosed subject matter.

FIG. 63 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 62.

FIG. 64 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 62.

FIGS. 65A-65D provide perspective FIG. 65A, right FIG. 65B, left FIG. 65C, and front FIG. 65D views of the sun gear shaft of the delivery system of FIG. 62.

FIGS. 66A-66D provide perspective FIG. 66A, right FIG. 66B, left FIG. 66C, and front FIG. 66D views of the planet carrier of the delivery system of FIG. 62.

FIGS. 67A-67D provide perspective FIG. 67A, right FIG. 67B, left FIG. 67C, and front FIG. 67D views of the ring gear of the delivery system of FIG. 62.

FIGS. 68A-68D provide perspective FIG. 68A, right FIG. 68B, left FIG. 68C, and front FIG. 68D views of the first clutch driver of the delivery system of FIG. 62.

FIGS. 69A-69D provide perspective FIG. 69A, right FIG. 69B, left FIG. 69C, and front FIG. 69D views of the clutch release of the delivery system of FIG. 62.

FIGS. 70A-70D provide perspective FIG. 70A, right FIG. 70B, left FIG. 70C, and front FIG. 70D views of the ratchet gear of the delivery system of FIG. 62.

FIGS. 71A-71D provide perspective FIG. 71A, right FIG. 71B, left FIG. 71C, and front FIG. 71D views of the sheath gondola of the delivery system of FIG. 62.

FIGS. 72A-72D provide perspective FIG. 72A, right FIG. 72B, left FIG. 72C, and front FIG. 72D views of the ratchet gondola of the delivery system of FIG. 62.

FIGS. 73A-73D provide perspective FIG. 73A, right FIG. 73B, left FIG. 73C, and front FIG. 73D views of the clutch ring of the delivery system of FIG. 62.

FIG. 74 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 62.

FIG. 75 is an enlarged in view of a portion of the delivery system of FIG. 63.

FIG. 76 provides a top perspective view of selected elements of the trigger assembly of the delivery system of FIG. 1.

FIGS. 77A-77D provide perspective FIG. 77A, right FIG. 77B, left FIG. 77C, and front FIG. 77D views of the trigger of the delivery system of FIG. 1.

FIGS. 78A-78D provide perspective FIG. 78A, right FIG. 78B, left FIG. 78C, and front FIG. 78D views of the trigger pinion of the delivery system of FIG. 1.

FIGS. 79A-79D provide perspective FIG. 79A, right FIG. 79B, left FIG. 79C, and front FIG. 79D views of the slide pinion of the delivery system of FIG. 1.

FIGS. 80A-80D provide perspective FIG. 80A, right FIG. 80B, left FIG. 80C, and front FIG. 80D views of the slide of the delivery system of FIG. 1.

FIGS. 81A-81D provide perspective FIG. 81A, right FIG. 81B, left FIG. 81C, and front FIG. 81D views of the base of the delivery system of FIG. 1.

FIG. 82 is a perspective view illustrating the relationship between selected elements of the delivery system of FIG. 1.

FIG. 83 provides a perspective view of the spring of the delivery system of FIG. 1.

FIGS. 84A-84C are various views depicting the spring support of the delivery system of FIG. 1.

FIGS. 85A-85D are various views depicting selected elements and the relationship between selected elements of the ratchet mechanism of the delivery system of FIG. 1.

FIG. 86 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 24.

FIG. 87 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 24.

FIGS. 88A-88D provide various views of selected elements and the relationship between selected elements of the ratchet mechanism of the delivery system of FIG. 24.

FIG. 89 is a perspective view of the delivery system of FIG. 36.

FIG. 90 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 36.

FIG. 91 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 36.

FIG. 92 is an exploded view of the delivery system of FIG. 46.

FIG. 93 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 52.

FIG. 94 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 52.

FIG. 95 is a right side view, with a portion of the handle housing removed, of the delivery system of FIG. 62.

FIG. 96 is a left side view, with a portion of the handle housing removed, of the delivery system of FIG. 62.

DETAILED DESCRIPTION

Reference will now be made in detail to the various exemplary embodiments of the disclosed subject matter, exemplary embodiments of which are illustrated in the accompanying drawings. The structure and corresponding method of making and using the disclosed subject matter will be described in conjunction with the detailed description of the delivery system. The methods and systems described herein can be used for delivering a medical device, such as a stent, scaffold stent graft, valve, filter, or other suitable implant to a desired location in a patient.

Generally, and as set forth in greater detail, the disclosed subject matter provided herein includes a delivery system having a handle, a trigger, and an actuation assembly. The trigger is operatively coupled to the handle. The actuation assembly is operatively coupled to the trigger, the inner shaft member, and the outer tubular member. As used herein the terms “functionally” and “operatively” as used with “coupled,” “engaged,” or “connected,” are interchangeable and understood by one of skill in the art. The actuation assembly includes a planet carrier, at least one planet gear operatively coupled to the planet carrier, a sun gear shaft operatively engaged with the planet gear, a ring gear operatively engaged with the planet gear, a first clutch driver configured to limit the sun gear shaft to uni-directional rotational motion, and a second clutch driver configured to uni-directionally lock the sun gear shaft and the planet carrier. The actuation assembly is configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and further wherein the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position.

In accordance with the described subject matter, a trigger assembly for a delivery system is also provided. The trigger assembly includes a trigger functionally connected to the actuation assembly by a driving rack, a gear train functionally disposed between the trigger and the driving rack. The gear train includes a trigger gear sector, a trigger pinion operatively meshed with the trigger gear sector, a slide pinion operatively coupled to the trigger pinion, and a slide rack disposed on a slide coupled to the driving rack and operatively meshed with the trigger pinion.

A variety of types of medical devices are suitable for delivery by the delivery system of the present invention. For purpose of illustration and not limitation, the delivery system is described herein with a medical device depicted as a self-expanding stent. Particularly, although not by limitation, reference is made herein to the implant being a braided stent or scaffold for purpose of illustration only. However, the delivery system presently disclosed is not limited to the delivery of self-expanding stents. Other devices can also be used. For example, scaffolds, coils, filters, stent grafts, embolic protection devices, and artificial valves can be delivered within a patient's vasculature, heart, or other organs and body lumens using the disclosed delivery system. Other devices such as a prosthesis retrieval mechanism can also be delivered with the delivery system to a predetermined location in a patient's luminal system. Moreover, a combination of medical devices and/or beneficial agents can also be delivered using the disclosed subject matter. For example, multiple stents and/or a combination of stents and embolic protection devices and/or beneficial agents can be delivered by the disclosed subject matter, as described below. Additional information related to delivery of implants can be found in U.S. application Ser. No. 11/876,764, filed on Oct. 22, 2007, and U.S. application Ser. No. 13/118,325, filed on May 27, 2011, each of which is incorporated by reference in its entirety herein.

Referring to FIG. 1 for the purpose of illustration and not limitation, various embodiments of the delivery systems disclosed herein generally can include a handle 1, an outer tubular member 22, and an inner shaft member 21. An implant 23, for example, a braided implant can be provided with the system or independently. The handle can include a trigger assembly including a trigger 60 movable between and first position and a second position, and an actuation assembly 2 (see e.g., FIG. 3) operatively coupled to the trigger 60. The outer tubular member 22 can include a proximal end portion and a distal end portion. The outer tubular member 22 can be operatively coupled to the actuation assembly 2 and can be movable in a proximal direction relative to the handle 1. A stabilizer tube (not shown) can be disposed over at least the proximal end portion of the outer tubular member 22, and a strain relief 15 can be used to couple the stabilizer tube and the handle 1. The inner shaft member 21 can include a proximal end portion and a distal end portion. The inner shaft member 21 can be disposed within the outer tubular member 22 and can be operatively coupled to the actuation assembly 2. The inner shaft member 21 of the disclosed delivery system is movable distally and proximally relative to the outer tubular member 22. The implant 23 can be disposed within the distal end portion of the outer tubular member 22 and can be positioned to be engaged by the distal end portion of the inner shaft member 21 when the inner shaft member is moved distally relative to the outer tubular member 22. The distal end portion of the inner shaft member 21 can have a pushing mechanism disposed thereon. For example, U.S. application Ser. No. 13/118,325, filed on May 27, 2011, which is incorporated by reference in its entirety herein, discloses suitable pusher elements for the delivery system. The outer tubular member 22 is depicted with a break in FIG. 1 to indicate that the length shown is only exemplary and the outer tubular member 22 and inner shaft member 21 can be longer than shown. Indeed, any suitable length can be used. As an example and not by way of limitation, the outer tubular member 22 and inner shaft member 21 can be long enough to extend from outside the body of a patient through a tortuous path to a treatment location within the body of a patient. The handle 1 can further include a luer lock at the proximal end of the handle to receive a guidewire therethrough which can extend through the inner shaft member and/or a flushing device as desired.

The actuation assembly 2 of the disclosed subject matter is configured to displace the outer tubular member 22 in the proximal direction a distance (d) relative to the handle 1 and to separately move the inner shaft member 21 distally a distance (x) relative to the handle 1 upon deployment of the trigger 60 from the first position to the second position. Furthermore, the actuation assembly 2 is configured to move the inner shaft member 21 proximally a distance (y) relative to the handle 1 with no displacement of the outer tubular member 22 relative to the handle 1 upon return of the trigger 60 from the second position to the first position. Put another way, the actuation assembly 2 can be configured to move the outer tubular member 22 in a proximal direction relative to the handle 1 and to separately move the inner shaft member 21 distally relative to the outer tubular member 22 upon deployment of the trigger 60 form the first position to the second position. The actuation assembly 2 can further be configured to move the inner shaft member 21 proximally relative to the outer tubular member 22 with no displacement of the outer tubular member 22 relative to the handle 1 upon return of the trigger 60 from the second position to the first position. Repeatedly deploying the trigger 60 from the first position to the second position and returning the trigger from the second position to the first position can cause the inner shaft member 21 to urge the implant 23 from the outer tubular member 22.

The distance (y) minus the distance (x) can be substantially equal to the distance (d). Upon deployment of the trigger 60 from the first position to the second position and return of the trigger 60 from the second position to the first position a net displacement of the inner shaft member 21 relative to the outer tubular member 22 thus can be zero. The implant 23 can have a length, and the length of the implant 23 can be less than the distance (x). Example lengths of the implant 23, for purpose of illustration and not limitation, can be 20 mm, 30 mm, 40 mm, 60 mm, 80 mm, 100 mm, 120 mm, and 150 mm.

The distances (d), (x) and (y) can be selected based at least in part on the diameter of the implant to be delivered, the desired compression of the implant to be delivered, the path between the insertion point and the location of implant delivery, and/or other variables. As an example, and not by way of limitation, for a stent having a diameter of 4.5 mm when delivered to the vasculature, (d) can be about 12 mm, (x) can be about 28 mm, and (y) can be about 40 mm. As another example and not by way of limitation, the ratio (referred to herein as the “gear ratio”) between the net distal motion of the inner shaft member 21 relative to the outer shaft member 22 (i.e., the distance (d) plus the distance (x)) to the distance (d) can be greater than 3. As an example, the gear ratio of (12+28):(12) is about 3.3. The actuation assembly disclosed herein having such a gear ratio can be used to properly deploy a braided stent from an extended delivery configuration to an expanded deployed configuration and address a 3:1 change in length of the stent from the delivery length to the deployment length. Exemplary diameters for stents when delivered to the vasculature can range from 4 mm to 12 mm or greater, such as, exemplary diameters can be 4.5 mm, 5.0 mm, 5.5 mm, 6.0 mm, 6.5 mm, 7.5 mm, or 8 mm, or suitable increments therebetween.

For the purpose of illustration, and not limitation, an exemplary embodiment of a system for delivering an implant is shown in FIG. 1 and is designated generally by reference character 1000. Portions of this exemplary embodiment are depicted in FIGS. 2-23. The handle 1 can include a first handle housing portion 1 a and a second handle housing portion 1 b. The system can also include a trigger 60. The trigger 60 can be operatively coupled to the handle, such that the trigger 60 can be moveable between a first position and a second position. As embodied herein, the trigger can be biased towards the first or second position, for example, by a spring. A ratchet mechanism 80 can be provided to prevent moving the trigger between the first and second positions, such as to require a full stroke in one or both directions as desired. Additionally, a trigger stop 67 (FIG. 2) can be provided. The trigger stop 67 can be disposed between the trigger 60 and the handle 1, and can limit how far the trigger 60 can be actuated. The size of trigger stop 67 can be selected based at least in part on the diameter of the stent to be delivered, the desired compression of the stent to be delivered, the path between the insertion point and the location of stent delivery, and/or other variables. Indeed, the system can include a trigger lock 1 e, which can prevent any motion of the trigger. For example, the trigger lock 1 e can be engaged prior to use (e.g., during shipping) and can be disengaged in anticipation of use of the system.

The system 1000 also includes an actuation assembly 2. The actuation assembly 2 is operatively coupled to the trigger 60, the inner shaft member 21 and the outer tubular member 22 to provide the desired relative movement as set for in detail above.

FIG. 4 shows for the purpose of illustration and not limitation, selected elements or components of the actuation assembly of the delivery system 1000. That is, FIGS. 5-11 show for the purpose of illustration and not limitation, selected components of an actuation assembly 2. FIGS. 12-23 show for the purpose of illustration and not limitation, the relationship between selected components of an actuation assembly 2. As noted above, the actuation assembly 2 can be configured to displace the outer tubular member 22 in the proximal direction a distance (d) relative to the handle 1 and to separately move the inner shaft member 21 distally a distance (x) relative to the handle 1 upon deployment of the trigger 60 from the first position to the second position. The actuation assembly 2 can be configured to move the inner shaft member 21 proximally a distance (y) relative to the handle 1 with no displacement of the outer tubular member 22 relative to the handle 1 upon return of the trigger 60 from the second position to the first position.

As depicted herein, the actuation assembly 2 can include a planetary gear system. For example, the actuation assembly can include a planet carrier 5, at least one planet gear 6, a sun gear shaft 3, a ring gear 7, a first clutch driver 4 a and a second clutch driver 4 b. The actuation assembly can include a shuttle frame 9. The shuttle frame can have the planet carrier 5, the planet gears 6, the sun gear shaft 3, the ring gear 7, and the first and second clutch drivers 4 a, 4 b disposed thereon. Shuttle frame 9 can be disposed within the handle 1 and can be moveable relative to the handle 1 along the length of the handle 1.

The sun gear shaft 3 (FIG. 5) can include a sun gear portion 3 a, a sheath pinion 3 b, a clutch engagement portion 3 c, and a step portion 3 d. As depicted herein, the clutch engagement portion 3 c can be saw-toothed, although other suitable configurations can be used. The planet carrier 5 (FIG. 6) can include a circumferential pinion 5 a, a clutch component 5 b, and at least one pin 5 c. The planet carrier 5 will include one pin 5 c for each planet gear 6. For example, as shown at least in FIG. 6, the planet carrier 5 includes three pins 5 c. The ring gear 7 (FIG. 7) can include a circumferential pinion 7 a and a ring gear portion 7 b. Each clutch driver 4 a, 4 b (FIG. 8) can be identical in shape, and can include a sun gear shaft engagement portion 4 c and a clutch portion 4 d. The sun gear shaft engagement portion 4 c can be saw-toothed, although other suitable configurations can be used.

The planet carrier 5 thus operates as the “planet carrier” of the planetary gear system. As such, the at least one planet gear 6 can be operatively coupled to the planet carrier 5. Each planet gear 6 can be operatively coupled to a pin 5 c of the planet carrier 5, as shown in FIG. 12 for the purpose of illustration and not limitation. In the exemplary embodiment, the system includes three planet gears 6 operating as the “planet gears” of the planetary gear system; however, one, two, four or more planet gears 6 can be provided. The sun gear shaft 3 can operate as the “sun gear” of the planetary system. The sun gear portion 3 a of the sun gear 3 can be operatively engaged with the planet gears 6 such that the planet gears 6 are operatively meshed with the sun gear portion 3 a, as shown in FIG. 13 for the purpose of illustration and not limitation. The ring gear 7 can operate as the “ring gear” of the planetary system. The ring gear portion 7 b can be operatively engaged with the planet gears 6 such that the planet gears 6 are operatively meshed with the ring gear portion 7 b of the ring gear 7, as shown in FIG. 14 for the purpose of illustration and not limitation. The step portion 3 d of the sun gear shaft 3 can be configured to maintain the position of the remaining portion the planetary gear system. For example, the step portion 3 d can engage the ring gear 7 and reduce undesired movement of the ring gear 7, which can reduce undesired movement of the planet gears 6.

As further depicted, the shuttle frame 9 (FIG. 9) can include a clutch engagement portion 9 a, a cavity 9 b which can be configured to receive a ferrule coupled to the proximal end of the outer tubular member 22, and a guide 9 c.

The second clutch driver 4 b can be configured to uni-directionally lock the sun gear shaft 3 and the planet carrier 5. As such, the sun gear shaft 3, planet carrier 5, and ring gear 7 have a 1:1 ratio of rotation during deployment of the trigger 60 from the first position to the second position. For example, the sun gear engagement portion 4 c of the second clutch driver 4 b can engage the clutch engagement portion 3 c of the sun gear shaft 3, such that the sun gear shaft 3 and the second clutch driver 4 b rotate together, as shown in FIG. 15, for the purpose of illustration and not limitation. Additionally, the clutch portion 4 d of the second clutch driver 4 b can have a ratchet-like engagement with the clutch component 5 b of the planet carrier 5, as shown in FIG. 16, for the purpose of illustration and not limitation. Such a configuration can allow the sun gear shaft 3 and planet carrier 5 to rotate independently of one another in a first direction (e.g., when the planet carrier 5 rotates in the counter clockwise direction in FIG. 16), and locked together in a second direction (e.g., when the planet carrier 5 rotates in the clockwise direction in FIG. 16).

The first clutch driver 4 a can be configured to limit the sun gear shaft 3 to uni-direction rotational motion. The first clutch driver 4 a and sun gear shaft 3 can be configured such that the sun gear shaft 3 does not rotate during return of the trigger from the second position to the first position. For example, the sun gear engagement portion 4 c of the first clutch driver 4 a can be fixedly engaged with the clutch engagement portion 3 c of the sun gear shaft 3, such that the sun gear shaft 3 and the first clutch driver 4 a rotate together, as shown in FIG. 15, for the purpose of illustration and not limitation. Additionally, the first clutch driver 4 a can have a ratchet-type engagement with a separate element, for example and as shown in FIG. 17 for the purpose of illustration and not limitation, a clutch engagement portion 9 a on the shuttle frame 9. As such, the first clutch driver 4 a can be limited to uni-direction motion by the clutch engagement portion 9 a, and thereby limit the sun gear shaft 3 to uni-directional motion (e.g., the sun gear shaft 3 can only rotate in the counterclockwise direct in FIG. 17).

The sun gear shaft 3 can be functionally coupled to the outer tubular member 22 such that upon deployment of the trigger from the first position to the second position, the sun gear shaft 3 rotates and thereby causes the outer tubular member 22 to move proximally. For example, the shuttle frame 9 can be fixedly coupled to the outer tubular member 22 at the cavity 9 b. As depicted herein for illustration, the shuttle frame 9 and outer tubular member 22 can be coupled by a ferrule. The sheath pinion portion 3 b of the sun gear shaft 3 can be functionally coupled to the handle 1 such that upon deployment of the trigger 60 from the first position to the second position the sun gear shaft 3 rotates, engages the handle 1, and moves the shuttle frame 9 proximally a distance relative to the handle 1. As such and as embodied herein the outer tubular member 22 also moves proximally relative to the handle 1 because it is fixedly coupled to the shuttle frame 9. Additionally, intermediate gear 10 can be functionally meshed between the sheath pinion potion 3 b and a sheath rack 1 c disposed on the handle 1, as shown in FIG. 18, for the purpose of illustration and not limitation. Additionally or alternatively, the sheath pinion portion 3 b can directly mesh the sheath rack 1 c. As noted herein above, the first clutch driver 4 b can prevent the sun gear shaft 3 from rotating during return of the trigger 60 from the second position to the first position. Accordingly, the shuttle frame 9, the outer tubular member 22 fixedly coupled thereto, and all other components carried by the shuttle frame 9, will move proximally when the trigger 60 is deployed from the first position to the second position, but remain stationary when the trigger 60 is returned from the second position to the first position as embodied herein. The gears of the small spur gear 10 b of the intermediate gear 10 (or the gears of the sheath pinion portion 3 b) and the gears of the sheath rack 1 c can utilize a non-standard pitch as desired or needed. As an example and not by way of limitation, a standard 48 pitch can be slightly enlarged. Such a change can allow the actuation assembly to achieve the desired value of (d) when the trigger 60 is deployed from the first position to the second position.

The actuation assembly 2 can also include a ratchet rack 8. The ratchet rack 8 can be fixedly coupled to the inner shaft member 21 and can be disposed on the shuttle frame 9, as shown in FIG. 19 for the purpose of illustration and not limitation. The ratchet rack 8 can be operatively engaged with the ring gear 7. For example, the ratchet rack 8 can be operatively meshed with the circumferential pinion 7 a of the ring gear 7, as shown in FIG. 20, for the purpose of illustration and not limitation. Upon deployment of the trigger 60 from the first position to the second position, the ring gear 7 can rotate and cause the ratchet rack 8, and therefore the inner shaft member 21, to move distally relative to the handle. Upon return of the trigger 60 from the second position to the first position, the ring gear 7 can rotate in the opposite direction and cause the ratchet rack 8, and therefore the inner shaft member 21, to move proximally relative to the handle.

The actuation assembly 2 can further include a plate 14 disposed on the shuttle assembly 9. The plate 14 can hold portions of the actuation assembly 2 in place and can protect the actuation assembly 2. The actuation assembly 2 can also include at least one pin 13 configured to engage at least one pin track disposed within the handle 1 to thereby guide the shuttle frame 9 along the handle, as shown in FIG. 21 for the purpose of illustration and not limitation. A pin track can be on the first side of the handle housing 1 a, the second side of the handle housing 1 b, or on both sides of handle 1. The at least one pin can include a first pin 13 a disposed through an axis of the sun gear shaft 3. The actuation assembly can include additional pins, such as a second pin 13 b and a third pin 13 c (FIG. 2), each disposed through the plate 14 and the shuttle frame 9. The second pin 13 b and third pin 13 c can hold the plate 14 in place on the shuttle frame 9. The actuation assembly 2 can include a fourth pin 13 d disposed through an axis of the intermediate gear 10. The fourth pin 13 d can engage the handle and act as a guide as the shuttle frame 9 moves relative to the handle 1.

In accordance with another aspect of the disclosed subject matter, the actuation assembly 2 can be functionally coupled to the trigger 60 by a driving rack 12. For example, the driving rack 12 can be fixedly coupled or releasably coupled to an intermediate element functionally disposed between the driving rack 12 and the trigger 60. As an example and not by way of limitation, the driving rack 12 can have a bayonet-type engagement with the intermediate element. The driving rack 12 can be operatively engaged with the planet carrier 5. For example, the driving rack 12 can be operatively meshed with the circumferential pinion 5 a of the planet carrier 5, as shown in FIG. 22 for the purpose of illustration and not limitation. The driving rack 12 can be supported in a guide 9 c disposed on the shuttle 9, as shown in FIG. 22 for the purpose of illustration and not limitation. Such a configuration can allow a limited region of contact between the driving rack 12 and the corresponding support surface, thereby reducing friction. Additionally, such a configuration can provide support proximal to the point of contact between the driving rack 12 and the planet carrier 5, even as that point moves along the length of the driving rack 12. In operation, upon deployment of the trigger 60 from the first position to the second position, the driving rack 12 can move distally, relative to the handle 1, and cause the planet carrier 5 to rotate in a first direction. Upon return of the trigger 60 from the second position to the first position, the driving rack 12 can move proximally relative to the handle, and cause the planet carrier 5 to rotate in an opposite direction.

In view of the disclosed subject matter, the dimensions and features of the trigger stop 67, shuttle 9 and elements disposed thereon, sheath rack 1 c, and the handle guide can be designed based on the specifics of the implant 23, for example, the diameter of the implant 23. As an example and not by way of limitation, for a given radius of the intermediate gear 10, the sheath rack 1 c and the handle guide, can be a specific distance apart to properly engage the small spur gear 10 b of the intermediate gear 10 and the pin 13 d disposed through the axis of the intermediate gear 10. If the radius of the intermediate gear is changed, the distance between the sheath rack 1 c and the handle guide can also be adjusted accordingly.

For purpose of illustration, reference is now made to the operation of the system with the actuation assembly disclosed herein. During operation, the user can deploy the trigger 60 from the first position to the second position (referred to herein as the “first action”). The trigger 60 thus can cause the driving rack 12 to move in the distal direction. The driving rack 12, functionally meshed with the circumferential pinion 5 a of the planet carrier 5, can impart rotational motion on the planet carrier 5. The planet carrier 5 can impart rotational motion on the three planet gears 6. The planet gears 6 can be constrained from rotating freely because they are meshed with the sun gear portion 3 a of the sun gear shaft 3. The three planet gears 6 can be meshed with the ring gear portion 7 b of the ring gear 7, and can impart rotational motion on the ring gear 7. The ring gear 7, can be operatively meshed with the ratchet rack 8, and can drive the ratchet rack 8 distally. The inner shaft member 21, which can be fixedly coupled to the ratchet rack 8, moves distally. The planet carrier 5 can be rotationally coupled to the sun gear shaft 3 by the second clutch driver 4 b when rotating in the first action; thus, rotation can be transmitted to the sun gear shaft 3 in a 1:1 ratio. The first clutch driver 4 a allows the sun gear shaft 3 to rotate freely relative to the shuttle frame 9 during the first action. The sheath pinion 3 b of the sun gear shaft 3 can be meshed with the large spur gear 10 a of the intermediate gear 10, and can impart rotational motion on the intermediate gear 10. The small spur gear 10 b of the intermediate gear 10 can be operatively meshed with a rack 1 c disposed on the second handle housing portion 1 b; thus, the rotational motion of the intermediate gear 10 can impart linear motion on the shuttle frame 9 in the proximal direction. The outer tubular member 22, which can be fixedly coupled to the shuttle frame 9 can move proximally relative to the handle. Thus, during the first action, the inner shaft member 21 can move distally relative to the handle 1 and the outer tubular member 22 can move proximally relative to the handle 1.

Upon return of the trigger 60 from the second position to the first position (herein referred to as the “second action”), the driving rack 12 can move proximally relative to the handle 1. The driving rack 12 can impart rotational motion to the planet carrier 5. The planet carrier 5 can transmit rotational motion to the three planet gears 6. The planet gears 6 can rotate about the sun gear shaft 3, which can be held stationary relative the shuttle frame 9 via the first clutch driver 4 a. The planet gears 6 can impart rotary motion to the ring gear 7. The ratio of motion between the planet carrier 5 and the ring gear 7 can be determined by the ratio of ring gear portion 7 b teeth to sun gear portion 3 a teeth (ratio=R/(R+S)). Linear motion can be transmitted to the ratchet rack 8 in the proximal direction by the ring gear 7. The inner shaft member 21 can move proximally relative to the handle 1. Thus, during the second action, the inner shaft member moves proximally relative to the handle 1 and the outer tubular member 22 is stationary relative to the handle.

As further embodied herein, the actuation assembly 2 can include a clutch release 11. The clutch release 11 can be operatively coupled to the second clutch driver 4 b and can be configured to prevent the second clutch driver 4 b from uni-directionally locking the sun gear shaft 3 and the planet carrier 5 when the clutch release 11 is engaged by a stop 1 d. For example, the clutch release 11 can prevent the clutch portion of the second clutch driver 4 b from engaging with the clutch component 5 b of the planet carrier 5 by urging elements of the clutch portion away from the clutch component 5 b, as shown in FIG. 23, for the purpose of illustration and not limitation. Thus, the clutch release 11 can prevent the sun gear shaft 3, planet carrier 5 and ring gear 7 rotating with a 1:1 ratio during the first motion. Rather, when the clutch release 11 is engaged by the stop 1 d, the ratio of motion between planet carrier 5 and the ring gear 7 is the same for the first motion and the second motion. The stop 1 d can be disposed on the handle 1, for example on the second handle housing portion 1 b. The stop 1 d can be configured to engage the clutch release 11 when the actuation assembly 2 has moved proximally a distance (z) along the handle 1. Any suitable distances for (z) can be used. The stop 1 d can be inserted into a receiving pocket disposed on the handle or otherwise secured with known techniques. The clutch release 11 can include a saw-tooth portion 11 a or other suitable configuration, and the stop 1 d can include a resilient abutment portion. The saw-tooth portion of the clutch 11 thus can be configured to engage the resilient abutment portion of the stop 1 d. As an example, the stop can be P-shaped stop that can provide compliance and opposing bias when the resilient abutment portion of the stop 1 d engages the saw-tooth portion of the clutch 11. Such a configuration can prevent or inhibit disengagement of the clutch release 11 and the clutch component 5 b of the planet carrier 5.

Referring now to FIG. 24 for the purpose of illustration and not limitation, another exemplary embodiment of a system for delivering an implant is provided and designated generally by reference character 1001. Portions of this exemplary embodiment are depicted in FIGS. 25-35. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1001 can be configured to deliver an implant in a similar manner as described herein above.

The delivery system 1001 can include a handle 101, an outer tubular member 122, an inner shaft member 121, and an implant 123, for example, a braided implant. The handle 101 can include a trigger 160 and an actuation assembly 102, which can be configured to move the inner shaft member 121 and the outer tubular member 122 relative to the handle 101 as described above upon deployment of the trigger 160 from the first position to the second position and return from the second position to the first position. The trigger 160 can include a lock as described herein above.

Referring now to FIGS. 25-35 for the purpose of illustration and not limitation, the actuation assembly 102 can include a planetary gear system. For purpose of illustration and not limitation, the actuation assembly 102 can be suitably similar to that of the previous embodiment. However, as an alternative to the actuation assembly of the previous embodiment, certain modifications can be incorporated. For example, the ratchet rack 108 can be operatively meshed with the planet carrier 105, and the driving rack 112 can be operatively meshed with the ring gear 107.

The actuation assembly 102 can include a sun gear shaft 103 (which can include a sun gear portion 103 a, a sheath pinion 103 b, and a clutch engagement portion 103 c; FIG. 27), a planet carrier 105 (which can include a circumferential pinion 105 a, a clutch component 105 b, and at least one pin 105 c; FIG. 28), at least one planet gear 106, a ring gear 107 (which can include a circumferential pinion 107 a and a ring gear portion 107 b; FIG. 29), a first clutch driver 104 a and a second clutch driver 104 b, both identical in shape (each can include a sun gear shaft engagement portion 104 c and a clutch portion 104 d; FIG. 30). The actuation assembly 102 can include a shuttle frame 109. The shuttle frame 109 can have the planet carrier 105, planet gears 106, sun gear shaft 103, ring gear 107, and first and second clutch drivers (104 a and 104 b) disposed thereon. The shuttle frame 109 can be disposed within the handle 101 and can be moveable relative to the handle 101 along the length of the handle 101. The shuttle frame 109 can include a clutch engagement portion 109 a, a cavity 109 b which can receive a ferrule coupled to the proximal end of the outer tubular member 122, and clips 109 d and 109 e, which can hold the planetary gear system in place on the shuttle frame 109. The planet carrier 105, planet gears 106, sun gear shaft 103 and ring gear 107 can perform as the respective elements of the planetary gear system as described above. The actuation assembly can also include a ratchet rack 108. The actuation assembly can be functionally coupled to the trigger 160 by a driving rack 112, which can be supported by the handle 101. The actuation assembly can include a clutch release 111 which can engage a stop 101 d disposed on the handle, as described herein above with regard to system 1000.

During operation, the user can deploy the trigger 160 from the first position to the second position (referred to herein as the “first action”). The trigger 160 can cause the driving rack 112 to move in a proximal direction. The driving rack 112, functionally meshed with the circumferential pinion 107 a of the ring gear 107, can impart rotational motion on the ring gear 107 (FIG. 34). The ring gear portion 107 b of the ring gear 107 can be operatively meshed with the planet gears 106, and can impart rotational motion on the planet gears 106. The planet gears 106 are operatively meshed with the sun gear portion 103 a of the sun gear shaft 103 and thus can be constrained from rotating freely because they. The movement of the planet gears 106, which are disposed on the pins 105 c of the planet carrier 105, can impart rotational motion on the planet carrier 105. The planet carrier 105 and the sun gear shaft 103 can be rotationally coupled by the second clutch driver 104 b when rotating in the first action; thus, rotation can be transmitted to the sun gear shaft 103 in a 1:1 ratio. The first clutch driver 104 a can allow the sun gear shaft 103 to rotate freely relative to the shuttle frame 109 during the first action. The sheath pinion 103 b of the sun gear shaft 103 can be meshed with the large spur gear 110 a of an intermediate gear 110, and can impart rotational motion on the intermediate gear 110. The small spur gear 110 b of the intermediate gear 110 can be operatively meshed with a rack 101 c disposed on the second handle housing portion 101 b; thus, the rotational motion of the intermediate gear 110 can impart linear motion on the shuttle frame 109 in the proximal direction. The outer tubular member 122, which can be fixedly coupled to the shuttle frame 109, can move proximally relative to the handle 101. The circumferential pinion 105 a of the planet carrier 105 can be operatively meshed with a ratchet rack 108, and rotation of the planet carrier 105 can move the ratchet rack 108 distally (FIG. 35). The inner shaft member 121, which can be fixedly coupled to the ratchet rack 108, moves distally. Thus, during the first action, the inner shaft member 121 can move distally relative to the handle 101 and the outer tubular member 122 can move proximally relative to the handle 101.

Upon return of the trigger 160 from the second position to the first position (herein referred to as the “second action”), the driving rack 112 can move distally relative to the handle 101. The driving rack 112 can impart rotational motion on the ring gear 107. The ring gear 107 can impart rotational motion on the three planet gears 106. The planet gears 106 can rotate about the sun gear shaft 103, which can be held stationary relative the shuttle frame 109 via the first clutch driver 104 a. The planet gears 106 can impart rotational motion on the planet carrier 105. Linear motion in the proximal direction can be transmitted to the ratchet rack 108 by the planet carrier 105. The inner shaft member 121, fixedly coupled to the ratchet rack 108, can move proximally relative to the handle 101. Thus, during the second action, the inner shaft member 121 can move proximally relative to the handle 101 and the outer tubular member 122 can be stationary relative to the handle 101.

Referring to FIG. 36 for the purpose of illustration and not limitation, an exemplary embodiment of a system for delivering an implant is provided and designated generally by reference character 1002. Portions of this exemplary embodiment are depicted in FIGS. 37-45. Elements that are similar to the previously described embodiments have been given like numbers, and unless described otherwise, the element can include the same features as described above. The delivery system 1002 can be configured to deliver an implant in a similar manner as described hereinabove.

The delivery system 1002 can include a handle 201, an outer tubular member 222, an inner shaft member 221, and an implant 223, for example, a braided implant. The handle 201 can include a trigger 260 and an actuation assembly 202, which can be configured to move the inner shaft member 221 and the outer tubular member 222 relative to the handle 201 as described above upon deployment of the trigger 260 from the first position to the second position and return from the second position to the first position. The trigger 260 can include a lock as described herein above.

Referring now to FIGS. 37-45 for the purpose of illustration and not limitation, the actuation assembly 202 can include a planetary gear system as embodied in delivery system 1001. For example, the actuation assembly 202 can include a sun gear shaft 203 (which can include a sun gear portion 203 a, a sheath pinion 203 b, and a clutch engagement portion 203 c; FIG. 39), a planet carrier 205 (which can include a circumferential pinion 205 a, a clutch component 205 b, and at least one pin 205 c; FIG. 40), at least one planet gear 206, a ring gear 207 (which can include a circumferential pinion 207 a and a ring gear portion 207 b; FIG. 41), a first clutch driver 204 a and a second clutch driver 204 b, both identical in shape (each can include sun gear shaft engagement portion 204 c and a clutch portion 204 d; FIG. 42). The actuation assembly 202 can include a shuttle frame 209. The shuttle frame 209 can have the planet carrier 205, planet gears 206, sun gear shaft 203, ring gear 207, and first and second clutch drivers (204 a and 204 b) disposed thereon. The shuttle frame 209 can be disposed within the handle 201 and can be moveable relative to the handle 201 along the length of the handle 201. The shuttle frame 209 can include a clutch engagement portion 209 a, a cavity 209 b which can receive a ferrule coupled to the proximal end of the outer tubular member 222, and clips 209 d and 209 e, which can hold the planetary gear system in place on the shuttle frame 209. The planet carrier 205, planet gears 206, sun gear shaft 203 and ring gear 207 can perform as the respective elements of the planetary gear system as described above. The actuation assembly can also include a ratchet rack 208. The actuation assembly can be functionally coupled to the trigger 260 by a driving rack 212, which can be supported by the handle 201. The actuation assembly can include a clutch release 211 which can engage a stop 201 d disposed on the handle, as described herein above with regard to system 1000.

During operation, the user can deploy the trigger 260 from the first position to the second position (referred to herein as the “first action”). The trigger 260 can cause the driving rack 212 to move in a proximal direction. The driving rack 212, functionally meshed with the circumferential pinion 207 a of the ring gear 207, can impart rotational motion on the ring gear 207. The ring gear portion 207 b of the ring gear 207 can be operatively meshed with the planet gears 106, and can impart rotational motion on the planet gears 206. The planet gears 206 can be constrained from rotating freely because they are operatively meshed with the sun gear portion 203 a of the sun gear shaft 203. The movement of the planet gears 206, which are disposed on the pins 205 c of the planet carrier 205, can impart rotational motion on the planet carrier 205. The planet carrier 205 and the sun gear shaft 203 can be rotationally coupled by the second clutch driver 204 b when rotating in the first action; thus, rotation can be transmitted to the sun gear shaft 203 in a 1:1 ratio. The first clutch driver 204 a can allow the sun gear shaft 203 to rotate freely relative to the shuttle frame 209 during the first action. The sheath pinion 203 b of the sun gear shaft 203 can be meshed with the large spur gear 210 a of an intermediate gear 210, and can impart rotational motion on the intermediate gear 210. The small spur gear 210 b of the intermediate gear 210 can be operatively meshed with a rack 201 c disposed on the second handle housing portion 201 b; thus, the rotational motion of the intermediate gear 210 can impart linear motion on the shuttle frame 209 in the proximal direction. The outer tubular member 222, which can be fixedly coupled to the shuttle frame 209 can move proximally relative to the handle 201. The circumferential pinion 205 a of the planet carrier 205 can be operatively meshed with a ratchet rack 208, and rotation of the planet carrier 205 can move the ratchet rack 208 distally. The inner shaft member 221, which can be fixedly coupled to the ratchet rack 208, moves distally. Thus, during the first action, the inner shaft member 221 can move distally relative to the handle 201 and the outer tubular member 222 can move proximally relative to the handle 101.

Upon return of the trigger 260 from the second position to the first position (herein referred to as the “second action”), the driving rack 212 can move distally relative to the handle 201. The driving rack 212 can impart rotational motion on the ring gear 207. The ring gear 207 can impart rotational motion on the three planet gears 206. The planet gears 206 can rotate about the sun gear shaft 203, which can be held stationary relative the shuttle frame 209 via the first clutch driver 204 a. The planet gears 106 can impart rotational motion on the planet carrier 205. Linear motion in the proximal direction can be transmitted to the ratchet rack 208 by the planet carrier 205. The inner shaft member 221, fixedly coupled to the ratchet rack 208, can move proximally relative to the handle 201. Thus, during the second action, the inner shaft member 221 can move proximally relative to the handle 201 and the outer tubular member 222 can be stationary relative to the handle 201.

Referring to FIG. 46 for the purpose of illustration and not limitation, an exemplary embodiment of a system for delivering an implant is provided and designated generally by reference character 1003. Portion of this exemplary embodiment are depicted in FIGS. 47-51. Elements that are similar to the previously described embodiments have been given like number, and unless described otherwise, the elements can include the same features as described above.

The delivery system 1003 can include a handle 301, an outer tubular member 322, an inner shaft member 321, and an implant 323, for example, a braided implant. The handle 301 can include a trigger 360 and an actuation assembly 302, which can be configured to move the inner shaft member 321 and the outer tubular member 322 relative to the handle 301 as described above upon deployment of the trigger 360 from the first position to the second position and return from the second position to the first position. The trigger 360 can include a lock as described herein above.

Referring now to FIGS. 47-51 for the purpose of illustration and not limitation, the actuation assembly 302 can include a planetary gear system as embodied in delivery system 1001. For example, the actuation assembly 302 can include a sun gear shaft 303 (which can include a sun gear portion 303 a, a sheath pinion 303 b, and a clutch engagement portion 303 c; FIG. 47), a planet carrier 305 (which can include a circumferential pinion 305 a, a clutch component 305 b, and a least one pin 305 c; FIG. 48), at least one planet gear 306, a ring gear 307 (which can include a circumferential pinion 307 a and a ring gear portion 307 b; FIG. 49), a first clutch driver 304 a and a second clutch driver 304 b, both identical in shape (each can include including a sun gear shaft engagement portion 304 c and a clutch portion 304 d; FIG. 50). The actuation assembly 302 can include a shuttle frame 309. The shuttle frame 309 can have the planet carrier 305, planet gears 306, sun gear shaft 303, ring gear 307, and first and second clutch drivers 304 a, 304 b disposed thereon. The shuttle frame 309 can be disposed within the handle 301 and can be moveable relative to the handle 301 along the length of the handle 301. The shuttle frame 309 can include clips 309 d and 309 e, which can hold the planetary gear system in place on the shuttle frame 309. The planet carrier 305, planet gears 306, sun gear shaft 303, and ring gear 307 can perform as the respective elements of the planetary gear system as described above. The actuation assembly can also include a ratchet rack 308. The actuation assembly can be functionally coupled to the trigger 360 by a driving rack 312, which can be supported by the handle 301.

During operation, the user can deploy the trigger 360 from the first position to the second position (referred to herein as the “first action”). The trigger 360 can cause the driving rack 312 to move in a proximal direction. The driving rack 312, functionally meshed with the circumferential pinion 307 a of the ring gear 307, can impart rotational motion on the ring gear 307. The ring gear portion 307 b of the ring gear 307 can be operatively meshed with the planet gears 306, and can impart rotational motion on the planet gears 306. The planet gears 306 can be constrained from rotating freely because they are operatively meshed with the sun gear portion 303 a of the sun gear shaft 303. The movement of the planet gears 306, which are disposed on the pins 305 c of the planet carrier 305, can impart rotational motion on the planet carrier 305. The planet carrier 305 and the sun gear shaft 303 are rotationally coupled by the second clutch driver 304 b when rotating in the first action; thus, rotation can be transmitted to the sun gear shaft 303 in a 1:1 ratio. The first clutch driver 304 a allows the sun gear shaft 303 to rotate freely relative to the shuttle frame 309 during the first action. The sheath pinion 303 b of the sun gear shaft 303 can be meshed a rack 301 c disposed on the second handle housing portion 301 b; thus, the rotational motion of the sun gear shaft 303 can impart linear motion on the shuttle frame 309 in the proximal direction. The outer tubular member 322, which can be fixedly coupled to the shuttle frame 309 can move proximally relative to the handle 301. The circumferential pinion 305 a of the planet carrier 305 can be operatively meshed with a ratchet rack 308, and rotation of the planet carrier 305 can move the ratchet rack 308 distally. The inner shaft member 321, which can be fixedly coupled to the ratchet rack 308, moves distally. Thus, during the first action, the inner shaft member 321 can move distally relative to the handle 301 and the outer tubular member 322 can move proximally relative to the handle 301.

Upon return of the trigger 360 from the second position to the first position (herein referred to as the “second action”), the driving rack 312 can move distally relative to the handle 301. The driving rack 312 can impart rotational motion on the ring gear 307. The ring gear 307 can impart rotational motion on the three planet gears 306. The planet gears 306 can rotate about the sun gear shaft 303, which can be held stationary relative the shuttle frame 309 via the first clutch driver 304 a. The planet gears 306 can impart rotational motion on the planet carrier 305. Linear motion can be transmitted to the ratchet rack 308 by the planet carrier 305. The inner shaft member 321 can move proximally relative to the handle 301. Thus, during the second action, the inner shaft member 321 can move proximally relative to the handle 301 and the outer tubular member 322 can be stationary relative to the handle 301.

Referring now to FIG. 52 for the purpose of illustration and not limitation, an exemplary embodiment of a system for delivering an implant is provided and designated generally by reference character 1004. Portions of this exemplary embodiment are depicted in FIGS. 53-61. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1004 can be configured to deliver an implant in a similar manner as described herein above.

The delivery system 1004 can include a handle 401, an outer tubular member 422, an inner shaft member 421, and an implant 423, for example, a braided implant. The handle 401 can include a trigger 460 and an actuation assembly 402, which can be configured to move the inner shaft member 421 and the outer tubular member 422 relative to the handle 401 as described above upon deployment of the trigger 460 from the first position to the second position and return from the second position to the first position. The trigger 460 can include a lock as described herein above.

Referring now to FIGS. 53-61 for the purpose of illustration and not limitation, the actuation assembly 402 can include a planetary gear system as embodied in delivery system 1000. For example, the actuation assembly 402 can include a sun gear shaft 403 (which can include a sun gear portion 403 a, a sheath pinion 403 b, and a clutch engagement portion 403 c; FIG. 55), a planet carrier 405 (which can include a circumferential pinion 405 a, a clutch component 405 b, and at least one pin 405 c; FIG. 56), at least one planet gear 406, a ring gear 407 (which can include a circumferential pinion 407 a and a ring gear portion 407 b; FIG. 57), a first clutch driver 404 a and a second clutch driver 404 b, both identical in shape (each can include including a sun gear shaft engagement portion 404 c and a clutch portion 404 d; FIG. 58). The actuation assembly 402 can include a shuttle frame 409. The shuttle frame 409 can have the planet carrier 405, planet gears 406, sun gear shaft 403, ring gear 407, and first and second clutch drivers (404 a and 404 b) disposed thereon. The shuttle frame 409 can be disposed within the handle 401 and can be moveable relative to the handle 401 along the length of the handle 401. The shuttle frame 409 can include a clutch engagement portion 409 a, a cavity 409 b which can receive a ferrule coupled to the proximal end of the outer tubular member 422, and a guide 409 c. The actuation assembly 402, can include a plate 414 disposed on the shuttle assembly 409. The plate 414 can hold portions of the actuation assembly 402 in place and can protect the actuation assembly 402. The actuation assembly 402 can include at least one pin 413 configured to engage at least one pin track disposed within the handle 401 to thereby guide the shuttle frame 409 along the handle. The at least one pin can include a first pin 413 a disposed through an axis of the sun gear shaft 403. The actuation assembly can include a second pin 413 b and a third pin 413 c, each disposed through the plate 414 and the shuttle frame 409. The second pin 413 b and third pin 413 c can hold the plate 414 in place on the shuttle frame 409. The actuation assembly 402 can include a fourth pin 413 d disposed through an axis of the intermediate gear 410. The fourth pin 413 d can engage the handle to guide the actuation assembly 402 as it moves relative to the handle 401. The actuation assembly can be functionally coupled to the trigger 460 by a driving rack 412, which can be supported in the guide 409 c. The actuation assembly can include a clutch release 411 which can engage a stop 401 d disposed on the handle, as described herein above with regard to system 1000.

During operation, the user can deploy the trigger 460 from the first position to the second position (referred to herein as the “first action”). The trigger 640 can cause the driving rack 412 to move in the distal direction. The driving rack 412, functionally meshed with the circumferential pinion 405 a of the planet carrier 405, can impart rotational motion on the planet carrier 405. The planet carrier 405 can impart rotational motion on the three planet gears 406. The planet gears 406 can be constrained from rotating freely because they can be meshed with the sun gear portion 403 a of the sun gear shaft 403. The three planet gears 406 can be meshed with the ring gear portion 407 b of the ring gear 407, and can impart rotational motion on the ring gear 407. The ring gear 407, which can be meshed with the ratchet rack 408, and can drive the ratchet rack 408 distally. The inner shaft member 421, which can be fixedly coupled to the ratchet rack 408, moves distally. The planet carrier 405 can be rotationally coupled to the sun gear shaft 403 by the second clutch driver 404 b when rotating in the first action; thus, rotation can be transmitted to the sun gear shaft 403 in a 1:1 ratio. The first clutch driver 404 a can allow the sun gear shaft 403 to rotate freely relative to the shuttle frame 409 during the first action. The sheath pinion 403 b of the sun gear shaft 403 can be meshed with the large spur gear 410 a of the intermediate gear 410, and can impart rotational motion on the intermediate gear 410. The small spur gear 410 b of the intermediate gear 410 can be operatively meshed with a rack 401 c disposed on the second handle housing portion 401 b; thus, the rotational motion of the intermediate gear 410 can impart linear motion on the shuttle frame 409 in the proximal direction. The outer tubular member 422, which can be fixedly coupled to the shuttle frame 409, can move proximally relative to the handle. Thus, during the first action, the inner shaft member 421 can move distally relative to the handle 401 and the outer tubular member 422 can move proximally relative to the handle 401.

Upon return of the trigger 460 from the second position to the first position (herein referred to as the “second action”), the driving rack 412 can move proximally relative to the handle 401. The driving rack 412 can impart rotational motion to the planet carrier 405. The planet carrier 405 can transmit rotational motion to the three planet gears 406. The planet gears 406 can rotate about the sun gear shaft 403, which can be held stationary relative the shuttle frame 409 via the first clutch driver 404 a. The planet gears 406 can impart rotary motion to the ring gear 407. Linear motion can be transmitted to the ratchet rack 408 in the proximal direction by the ring gear 407. The inner shaft member 421, which can be fixedly coupled to the ratchet rack 408, can move proximally relative to the handle 401. Thus, during the second action, the inner shaft member moves proximally relative to the handle 401 and the outer tubular member 422 can be stationary relative to the handle.

Referring to FIG. 62 for the purpose of illustration and not limitation, an exemplary embodiment of a system for delivering an implant is provided and designated generally by reference character 1005. Portions of this exemplary embodiment are depicted in FIGS. 63-75. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1005 can be configured to deliver an implant in a similar manner as described herein above.

The delivery system 1005 can include a handle 501, an outer tubular member 522, an inner shaft member 521, and an implant 523, for example, a braided implant. The handle 501 can include a trigger 560 and an actuation assembly 502, which can be configured to move the inner shaft member 521 and the outer tubular member 522 relative to the handle 501 as described above upon deployment of the trigger 560 from the first position to the second position and return from the second position to the first position. The trigger 560 can include a lock as described herein above.

Referring now to FIGS. 63-75 for the purpose of illustration and not limitation, the actuation assembly 502 can include a planetary gear system similar to the planetary gear system disclosed in system 1000. In lieu of a shuttle frame and a ratchet rack coupled to the outer tubular member and inner shaft member, respectively, the system 1005 can include gondolas disposed on tension elements, as described further below.

For example, the actuation assembly 502 can include a sun gear shaft 503 (which can include a sun gear portion 503 a, a clutch engagement portion 503 c, and a sheath gear engagement portion 503 d; FIG. 65), a planet carrier 505 (which can include a circumferential pinion 505 a, a clutch component 505 b, and at least one pin 505 c; FIG. 66), at least one planet gear 456, a ring gear 507 (which can include a circumferential pinion 507 a and a ring gear portion 507 b; FIG. 67), a first clutch driver 404 a and a second clutch driver 404 b, both identical in shape (each can include including a sun gear shaft engagement portion 504 c and a clutch portion 504 d; FIG. 68). The actuation assembly can include a sheath gear 524, which can engage the sheath gear engagement portion 503 d of the sun gear shaft 503. The actuation assembly can include a first tension element 525, and a sheath gondola 526 disposed on the first tension element. The first tension element can be functionally coupled to the sheath gear 524. The sheath gondola 526 can be fixedly coupled to the outer tubular member 522. The actuation assembly can include a second tension element 527, and a ratchet gondola 528 disposed on the second tension element. The second tension element 527 can be functionally coupled to the circumferential pinion 507 a of the ring gear 507. The ratchet gondola 528 can be fixedly attached the inner shaft member 521. The actuation assembly can include a clutch ring 531, which can be fixedly placed within the handle 501 and can provide a clutch engagement portion for the first clutch driver 501 a. Alternatively, the handle 501 can include a clutch engagement portion to engage the first clutch driver 501 a. The system can further include a plurality of pulley elements 529, which can be used to guide the first and second tension elements, and at least two tensioners 530 a, 530 b, which can be used to achieve the desired tension in the first and second tension elements. The actuation assembly can be functionally coupled to the trigger 560 by a driving rack 512. The actuation assembly can include a clutch release 511 which can engage a stop 501 e disposed within the handle, and configured to engage the clutch release 511 when the sheath gondola has moved the stop 501 e into place.

During operation, the user can deploy the trigger 560 from the first position to the second position (referred to herein as the “first action”). The trigger 540 can cause the driving rack 512 to move in the distal direction. The driving rack 512, functionally meshed with the circumferential pinion 505 a of the planet carrier 505, can impart rotational motion on the planet carrier 505. The planet carrier 505 can impart rotational motion on the three planet gears 506. The planet gears 506 can be constrained from rotating freely because they can be meshed with the sun gear portion 503 a of the sun gear shaft 503. The three planet gears 506 can be meshed with the ring gear portion 507 b of the ring gear 507, and can impart rotational motion on the ring gear 407. The ring gear 507, which can be functionally coupled to the ratchet gondola 528 by the second tension element 527, can cause the ratchet gondola 528 to move distally. The inner shaft member 521, which can be fixedly coupled to the ratchet gondola 528, can move distally. The planet carrier 505 can be rotationally coupled to the sun gear shaft 503 by the second clutch driver 504 b when rotating in the first action; thus, rotation can be transmitted to the sun gear shaft 503 in a 1:1 ratio. The first clutch driver 504 a can allow the sun gear shaft 503 to rotate freely relative to the clutch ring 531 during the first action. The sheath gear engagement portion 503 d of the sun gear shaft 503 can functionally engage the sheath gear 524, and can impart rotational motion on sheath gear 524. The sheath gear 524, which can be functionally coupled to the sheath gondola 526 by the first tension element 525, can cause the sheath gondola 526 to move proximally. The outer tubular member 522, which can be fixedly coupled to the sheath gondola 526, can move proximally relative to the handle. Thus, during the first action, the inner shaft member 521 can move distally relative to the handle 501 and the outer tubular member 522 can move proximally relative to the handle 501.

Upon return of the trigger 560 from the second position to the first position (herein referred to as the “second action”), the driving rack 512 can move proximally relative to the handle 501. The driving rack 512 can impart rotational motion to the planet carrier 505. The planet carrier 505 can transmit rotational motion to the three planet gears 506. The planet gears 506 can rotate about the sun gear shaft 503, which can be held stationary relative the clutch ring 531 via the first clutch driver 504 a. The planet gears 506 can impart rotary motion to the ring gear 507. The ring gear 507 can drive the ratchet gondola 528 proximally via the second tension element 527. The inner shaft member 521, which can be fixedly coupled to the ratchet gondola 528, can move proximally relative to the handle 501. Thus, during the second action, the inner shaft member can move proximally relative to the handle 501 and the outer tubular member 422 can be stationary relative to the handle.

In accordance with the described subject matter, and as noted above, a trigger assembly for a delivery system is also provided. The trigger assembly includes a trigger functionally connected to the actuation assembly by a driving rack, a gear train functionally disposed between the trigger and the driving rack. The gear train includes a trigger gear sector, a trigger pinion operatively meshed with the trigger gear sector, a slide pinion operatively coupled to the trigger pinion, and a slide rack disposed on a slide coupled to the driving rack and operatively meshed with the trigger pinion.

With regard to the trigger assembly, FIGS. 76-85 depict portions of the delivery system 1000 described herein above. The trigger 60 is operatively coupled to the handle and moveable between a first position and a second position. Furthermore the trigger can be biased towards the first and/or second position, for example, by a spring 91 (FIG. 83). As described in further detail below, the trigger assembly can further include a ratchet mechanism 80 which can prevent moving the trigger between the first and second positions. Particularly, the ratchet can be configured to require a full stroke of the trigger in one direction to allow motion of the trigger in the opposite direction.

As embodied herein, and with reference to FIG. 2, the trigger 60 can be coupled to the actuation assembly 2 by a driving rack 12. For example, the trigger 60 can be functionally coupled to the driving rack by gear train. The gear train can include a trigger gear sector 63 (FIG. 77), a trigger pinion 64 (FIG. 78), a slide pinion 65 (FIG. 79), a slide 61 (FIG. 80; sometimes referred to as an intermediate element) having a slide rack 66, and a base 81 that can support certain elements of the gear train (FIG. 81). The trigger 63 can be pivotally coupled to the base 81. The trigger gear sector 63 can be coupled to the trigger 60, for example, the trigger gear sector 63 can be unitary with the trigger 60, and can be operatively meshed with the trigger pinion 64. The trigger pinion 64 can be operatively coupled to the slide pinion 65. For example, the trigger pinion 64 and the slide pinion 65 can be coupled by splines and grooves, such as, four splines on the trigger pinion 64 configured to be received by four grooves in the slide pinion 65 as depicted in FIGS. 78 and 79. The slide pinion 65 can be operatively meshed with the slide rack 66 disposed on the slide 61. The driving rack 12 can be coupled to the slide 61. The driving rack 12 can be fixedly coupled or releasably coupled to the slide 61. As an example and not by way of limitation, the driving rack 12 can have a bayonet-type engagement with the slide 61. Furthermore, more than one trigger gear sector and/or trigger pinion can be provided, as shown, for example, in FIGS. 1-3, and 76, the gear train can include two trigger gear sectors 63 and two trigger pinions 64. Each of the trigger pinions 64 can be coupled to the slide pinion 65 as described above.

As embodied herein, the slide pinion 65 can be quad symmetrical. For example, the slide pinion 65 can have 28 teeth evenly distributed in sets of 7. The number of grooves can be a factor of the number of teeth, for example, 4 grooves and 28 teeth. Such a configuration can allow for symmetry between the teeth and the grooves of the slide pinion 65, and thus ease of assembly and/or use. Accordingly, when the slide pinion 65 is coupled the trigger pinion 64, the teeth are in proper alignment. Additionally or alternatively, the slide pinion 65 can include teeth around only a portion of the circumference. For example, rather than including teeth about the entire circumference, a number of teeth (e.g., 10 teeth) can be removed or omitted. This arrangement can accommodate other elements, for example, the movement of spring 90 (described in greater detail below) toward the slide pinion 65 during movement of the trigger 60 when space is restricted. Furthermore, at least one spline can be configured to align radially a selected location, e.g., a missing tooth, so as to allow for self-alignment.

With reference to FIGS. 83 and 84, for the purpose of illustration and limitation, a spring 90 can be provided. The spring can be, for example, a torsion spring 90. Additional springs can likewise be provided, e.g., two springs 90, as depicted in FIG. 76. The spring 90 can be coupled to the trigger such that energy is stored in the spring 90 upon deployment of the trigger 60 from the first position to the second position. The energy stored in the spring 90 thus can be configured to bias the trigger 60 to return from the second position to the first position. The spring 90 can be housed within a spring support 91 (FIG. 84). The spring support can be coupled to the trigger 60 and the base 81. The spring support 91 can house the spring 90 such that energy is stored in the spring 90 when the trigger 60 is in the first position, e.g., the spring support 91 can hold the spring 90 in a pre-loaded position. Such a configuration can cause a force to be felt as the user initially begins to move the trigger 60 from the first position to the second position. Additionally, by providing such a configuration, the spring can provide additional force or bias to assist in returning the trigger 60 from the second position to the first position, and thus ensure that the trigger 60 returns from the second position to the first position.

The spring support 90 can be configured to house and/or strengthen the spring, such as an exoskeleton arrangement. For example, the spring support 90 can have legs configured to engage the legs of the torsion spring 90, as depicted in FIG. 84. The legs of the spring support 91 can be configured to move with the legs of the torsion spring 90. If the spring includes a barrel portion, the spring support 91 can also include a barrel portion to accommodate the barrel portion of the spring 90. The spring support 91 can be a single piece element, or can include several elements coupled together to form the spring support (FIG. 84C). The elements when assembled thus can be configured to allow the spring support to move with the spring 90, but prevent the spring from fully relaxing. The spring support 91 thus can reduce or prevent loads on other elements of the delivery system, for example, the trigger 60 and the base 81, which can be plastic. That is, the spring support 91 can be made from metal or other suitably strong materials, preferably such materials that are not susceptible to creep under stress.

In accordance with another aspect of the disclosed subject matter, the delivery system can include a ratchet mechanism. With reference to FIG. 85, for the purpose of illustration and not limitation, the system can include ratchet mechanism 80. The ratchet mechanism 80 can include a first state and a second state. The first state can be configured to allow the trigger 60 to move toward the second position and prohibit motion toward the first position. The second state can be configured to allow the trigger 60 to move toward the first position and prohibit motion toward the second position. Such a system thus can be configured to require the user to perform a full stroke of the trigger 60 between the first and second position before allowing return movement in the opposite direction.

The ratchet mechanism 80 can include a first pawl 82. The first pawl 82 can be supported by a peg 86 coupled to the base 81. The first pawl 82 can pivot relative the peg, and thus relative the base 81. The first pawl 82 can also be coupled to one end of a ratchet spring 87 (not shown for purpose of clarity), which can be coupled to the base 81 at its opposite end. The ratchet mechanism 80 also can include a trigger ratchet rack 83 and the like. The trigger ratchet rack 83 can be disposed on the slide 61. The trigger ratchet rack 83 can be configured to engage the first pawl 82 to permit unidirectional motion of the slide 61. By limiting the slide 61 to unidirectional motion, the trigger can likewise be limited to unidirectional motion (i.e., toward the first state or toward the second state). The first pawl 82 can have a first state configured to allow the trigger 60 to move toward the second position and prohibit motion toward the first position and a second state configured to allow the trigger 60 to move toward the first position and prohibit motion toward the second position. The ratchet spring 87 can keep the pawl 82 biased toward the first position or the second position, selectively. That is, the pawl 82 can be configured to switch from the first state to the second state as the trigger approaches the second position from the first position. Likewise, the pawl 82 can be configured to switch from the second state to the first state as the trigger approaches the first position from the second position. For example and not by way of limitation, the trigger ratchet rack 83 can be configured to move past the first pawl 83, as the trigger approaches either the first position or the second position, respectively, and thus allow the first pawl 82 to move freely to the alternate state due to the bias of ratchet spring 87. As described herein, the pawl 83 can engage the ratchet rack 83 in both the first position and the second position. Additionally or alternatively, the ratchet mechanism can be configured with more than one rack, for example a dual rack, and the pawl 83 can engage a different rack in each state. The pawl 82 can be moved out of the first or second position to a third position (e.g., a defeated position) in which the pawl 82 does not engage the trigger ratchet rack 83. As an example, the pawl 82 can be moved to the defeated position by moving the pawl 83 perpendicular to the trigger ratchet rack 83 along peg 86. The base 81 can include a defeat hole 81 a (FIG. 81C), which can be aligned with the pawl 82 and can be aligned with a similar defeat hole in the handle 1, such that the pawl 82 can be defeated by pushing an instrument through the defeat holes and urging the pawl 82 along the peg 86. Peg 86 can be configured to prevent the pawl 82 from returning to the first or second positions once the pawl has been moved to the defeated position. For example and as shown in FIG. 85D, the peg 86 can have a variable diameter. The pawl 82 can be disposed on the larger diameter in the first or second position, and can be disposed on the smaller diameter in the defeated position. Furthermore, a damper can be disposed on the pawl 82, for example rubber, for reduced noise. The ratchet spring 87 can also be dampened.

For purpose of illustration, reference is now made to the operation of the system with the actuation assembly disclosed herein. In operation, the user can deploy the trigger 60 from the first position to the second position (referred to herein as the “first action”). The trigger can cause movement of the trigger gear sector 63. The trigger gear sector 63 can be functionally meshed with the trigger pinion 64 and can cause rotation of the trigger pinion 64. The trigger pinion 64 can be operatively coupled to the slide pinion 65, and can cause rotation of the slide pinion 65. The slide pinion 65 can be functionally engaged with the slide rack 66 and can cause the slide rack 66 to move distally. The slide rack 66 can be coupled to the driving rack 12, and the driving rack 12 can also move distally. The driving rack 12 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 21 to move distally relative to the handle, and the outer tubular member to move proximally relative to the handle, as described herein above. Thus and as noted above, during the first action, the inner shaft member 21 can move distally relative to the handle 1 and the outer tubular member 22 can move proximally relative to the handle 1. During the first action, the pawl 82 can be in the first state and can be configured to allow the trigger 60 to move toward the second position and prohibit motion toward the first position. The pawl 82 can be configured to switch from the first state to the second state as the trigger approaches the second position from the first position.

Upon return of the trigger 60 from the second position to the first position (herein referred to as the “second action”), which can be caused, for example, by the energy stored in the spring 90, the trigger can cause movement of the trigger gear sector 63 in the opposition direction as the first action. The trigger gear sector 63 can cause rotation of the trigger pinion 64. The trigger pinion 64 can cause rotation of the slide pinion 65. The slide pinion 65 can cause the slide rack 66 to move proximally. The driving rack 12 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 21 to move proximally relative to the handle, and the outer tubular member 22 remain stationary relative to the handle, as described herein above. Thus and as noted above, during the second action, the inner shaft member 21 moves proximally relative to the handle 1 and the outer tubular member 22 is stationary relative to the handle. During the second action, the pawl 82 can be in the second state and can be configured to allow the trigger 60 to move toward the first position and prohibit motion toward the second position. The pawl 82 can be configured to switch from the second state to the first state as the trigger approaches the first position from the second position.

In accordance with an alternative embodiment of the disclosed subject matter, a delivery system is provided wherein the trigger is coupled to the driving rack by a plurality of link elements. FIGS. 86-88 depict for the purpose of illustration and not limitation, portions of the delivery system 1001 described herein above. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1001 can be configured to deliver an implant in a similar manner as described herein above.

With reference to the exemplary embodiment herein, the trigger 160 can be coupled to the driving rack 112 by a plurality of link elements. The link elements can include a first and second linear links 171 and 172, a triangle link 173, and a slide 161. A base 181 can support the slide 161 and can have a trigger ratchet rack 183 disposed thereon. The first linear link 171 can be coupled to the trigger 160 at a first joint 174. The second linear link can be coupled to the slide 161 at a second joint 175. The triangle link 173 can be coupled to the first linear link 171 at a third joint 176 and the second linear link 172 at a fourth joint 177. The triangle link 173 can be coupled to the handle at a fifth joint 178 and the trigger 160 can be coupled to the handle at a sixth joint 179. Each of the first, second, third, fourth, fifth, and sixth joints (174-179) can be pivot joints. The third joint 176, fourth joint 177, and fifth joint 178 can define a triangle. The slide 161 can be coupled to the driving rack 112. The driving rack 112 can be fixedly coupled or releasably coupled to the slide 161. As an example and not by way of limitation, the driving rack 112 can have a bayonet-type engagement with the slide 161 (sometimes referred to herein as an intermediate element). A spring (not shown), such as a constant force spring or tape measure spring, can be coupled to the slide 161 and configured to bias the trigger 160 toward the first position. The spring can be supported in base 181. In particular embodiments, the spring can be coupled to any suitable link of the plurality of links to bias the trigger 160 toward the first position.

With reference to FIG. 88, for the purpose of illustration and not limitation, the system can also include a ratchet mechanism 180. The ratchet mechanism 180 can include a first state and a second state. The first state can be configured to allow the trigger 160 to move toward the second position and prohibit motion toward the first position. The second state can be configured to allow the trigger 160 to move toward the first position and prohibit motion toward the second position. Such a system can be configured to require the user to perform a full stroke of the trigger 160 between the first and second position, such as described above.

As embodied herein, for illustration and not limitation, the ratchet mechanism 180 can include a first pawl 182 as well as a second pawl 184. The first and second pawls 182 and 184 can be supported on the slide 161 and can include a ratchet trip 185 disposed between the first and second pawls 182 and 184. The first and second pawls 182 and 184 can each have a first state in which the pawls engage the trigger ratchet rack 183 to permit unidirectional motion of the slide. The first pawl 182 can allow motion in a first direction and the second pawl 182 can allow motion in a second direction. The first and second pawls 182 and 184 can each have a second state wherein the first and second pawls 182 and 184 do not engage the trigger ratchet rack 183. That is, when the first pawl 182 is in the first state the second pawl 184 can be in the second state, and when the second pawl 184 is in the first state the first pawl 182 can be in the second state. As the trigger 160 approaches the second position from the first position, the ratchet trip 185 can cause the first pawl 182 to switch (or disengage) to from the first state to the second state and the ratchet trip 185 can cause the second pawl 184 to switch (or engage) from the second state to the first state. Likewise, as the trigger 160 approaches the first position from the second position, the ratchet trip 185 can cause the first pawl 182 to switch (or engage) from the second state to the first state and the ratchet trip 185 can cause the second pawl 184 to switch (or disengage) from the first state to the second state. The system can be configured to ensure that the pawls are not simultaneous in the first state. The first pawl 182 and the second pawl 184 can each be in the second position at the same time to defeat the ratchet mechanism 180. Furthermore, the pawls and springs can be damped as described hereinabove.

In operation of this exemplary embodiment, the user can deploy the trigger 160 from the first position to the second position (referred to herein as the “first action”). The trigger 160 can pivot at the sixth joint 179 (clockwise in FIG. 86). The trigger 160 can pull on the first linear link 171, which can cause the triangle link 173 to pivot at fifth joint 178 (counter clockwise in FIG. 86). The triangle link 173 can pull second linear link 172 proximally, which can pull slide 161, and therefore driving rack 112, proximally. The driving rack 112 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 121 to move distally relative to the handle, and the outer tubular member 222 to move proximally relative to the handle, as described above. Thus and as noted above, during the first action, the inner shaft member 121 can move distally relative to the handle 101 and the outer tubular member 122 can move proximally relative to the handle 101. During the first action, the first pawl 182 can be in the first state and can be configured to allow the trigger 160 to move toward the second position and prohibit motion toward the first position. The second pawl 184 can be in the second position, and thus not engaged with the trigger ratchet rack 183. First and second pawls 182 and 184 can be configured to switch from the first state to the second state and from the second state to the first state, respectively, as the trigger approaches the second position from the first position. The transition of each pawl can be timed such that each pawl 182 and 184 is in the second state for a period of time before the second pawl 184 switches to the first state.

Upon return of the trigger 160 from the second position to the first position (herein referred to as the “second action”), which can be caused, for example, by the energy stored in the spring 190, the trigger 160 can pivot at the sixth joint 179 (counter clockwise in FIG. 86). The trigger can push on the first linear link 171, which can cause the triangle link 173 to pivot at fifth joint 178 (clockwise in FIG. 86). The triangle link 173 can push the second linear link 172 distally, which can push slide 161, and therefore driving rack 112, distally. The driving rack 112 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 121 to move proximally relative to the handle, and the outer tubular member 122 remain stationary relative to the handle, as described above. Thus and as noted above, during the second action, the inner shaft member 121 moves proximally relative to the handle 101 and the outer tubular member 122 is stationary relative to the handle. During the second action, the second pawl 184 can be in the first state and can be configured to allow the trigger 160 to move toward the first position and prohibit motion toward the second position. The first pawl 182 can be in the second position and thus not engaged with the trigger ratchet rack 183. First and second pawls 182 and 184 thus can be configured to switch from the second state to the first state and from the first state to the second state, respectively, as the trigger approaches the first position from the second position. Additionally or alternatively, the transition of each pawl can be timed such that each pawl 182 and 184 is in the second state for a desired period of time before the first pawl 182 switches to the first state.

As embodied herein, upon deployment of the trigger 160 from the first position to the second position and return of the trigger 160 from the second position to the first position, the third joint 176 can trace a non-linear path. Such non-linear motion can result in a variable force required to move the trigger 160 between positions along the path of the trigger 160.

In accordance with an alternative embodiment of the disclosed subject matter, a delivery system is provided wherein the trigger is coupled to the driving rack by a trigger pulley system. Referring now to FIG. 88 for the purpose of illustration and not limitation, a perspective view of delivery system 1002 is provided. Portions of this exemplary embodiment are depicted in FIGS. 90 and 91. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1002 can be configured to deliver an implant in a similar manner as described herein above.

The trigger 260 can be coupled to the driving rack 212 by a trigger pulley system. For example, the trigger 260 can be coupled to the handle at joint 279, which can be a pivot joint. The trigger 260 can be coupled to the slide 261 by a tether 288. The slide 261 can be coupled to the driving rack 212. The driving rack 212 can be fixedly coupled or releasably coupled to the slide 261. As an example and not by way of limitation, the driving rack 212 can have a bayonet-type engagement with the slide 261 (sometimes referred to herein as an intermediate element). Additionally, the slide can be coupled to a spring 290, for example, a constant force spring. The spring 290 can bias the slide toward a distal position and the trigger 260 in the first position. The spring can be supported in base 281. Additionally, the handle 201 can include a window 289 (FIG. 89), which can be used to manually move the slide.

In operation, the user can deploy the trigger 260 from the first position to the second position (referred to herein as the “first action”). The trigger 260 can pivot at the joint 279 (clockwise in FIG. 90). The tether 288 coupled to the trigger 260 and the slide 261 can pull the slide 261, and therefore the driving rack 212, proximally. The driving rack 212 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 221 to move distally relative to the handle, and the outer tubular member 222 to move proximally relative to the handle, as described hereinabove. Thus and as noted above, during the first action, the inner shaft member 221 can move distally relative to the handle 201 and the outer tubular member 222 can move proximally relative to the handle 201.

Upon return of the trigger 260 from the second position to the first position (herein referred to as the “second action”), which can be caused, for example, by the energy stored in the spring 290 pulling the slide 261 distally, the driving rack 212 can be moved distally. The driving rack 212 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 221 to move proximally relative to the handle, and the outer tubular member 222 remain stationary relative to the handle, as described hereinabove. Thus and as noted above, during the second action, the inner shaft member 221 moves proximally relative to the handle 201 and the outer tubular member 222 is stationary relative to the handle.

Referring now to FIG. 92 for the purpose of illustration and not limitation, an exploded view of delivery system 1003 is provided. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1003 can be configured to deliver an implant in a similar manner as described herein above.

The trigger 360 can include a slide 361 that can include an engagement surface 362 to be engaged by the user. The driving rack 312 can be fixedly coupled or releasably coupled to the slide 361. As an example and not by way of limitation, the driving rack 312 and the slide 361 can be a unitary member. The trigger 360 can be coupled to a spring, which can bias the trigger 360 toward the first position.

During operation, the user can deploy the trigger 360 from the first position to the second position (referred to herein as the “first action”). The trigger, and therefore the slide 361 and the driving rack 312, can move in a proximal direction. The driving rack 312 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 321 to move distally relative to the handle, and the outer tubular member 322 to move proximally relative to the handle, as described above. Thus and as noted above, during the first action, the inner shaft member 321 can move distally relative to the handle 301 and the outer tubular member 322 can move proximally relative to the handle 301.

Upon return of the trigger 360 from the second position to the first position (hereinafter referred to as the “second action”), the trigger 360, and therefore the slide 361 and the driving rack 312 can move in a distally relative to the handle 301. The driving rack 312 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 321 to move proximally relative to the handle, and the outer tubular member 322 remain stationary relative to the handle, as described above. Thus and as noted above, during the second action, the inner shaft member 321 moves proximally relative to the handle 301 and the outer tubular member 322 is stationary relative to the handle.

FIGS. 93 and 94 provide, for the purpose of illustration and not limitation, portion of delivery system 1004. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1004 can be configured to deliver an implant in a similar manner as described herein above.

The trigger 460 can include a slide 461 that can include an engagement surface 462 to be engaged by the user. The driving rack 412 can be fixedly coupled or releasably coupled to the slide 461. As an example and not by way of limitation, the driving rack 412 and the slide 461 can be a unitary member. The trigger 460 can be coupled to a spring, which can bias the trigger 460 toward the first position.

During operation, the user can deploy the trigger 460 from the first position to the second position (referred to herein as the “first action”). The trigger, and therefore the slide 461 and the driving rack 412, can move in a distal direction. The driving rack 412 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 421 to move distally relative to the handle, and the outer tubular member 422 to move proximally relative to the handle, as described above. Thus and as noted above, during the first action, the inner shaft member 421 can move distally relative to the handle 301 and the outer tubular member 422 can move proximally relative to the handle 401.

Upon return of the trigger 460 from the second position to the first position (herein referred to as the “second action”), the trigger 460, and therefore the slide 461 and the driving rack 412 can move in a proximal relative to the handle 401. The driving rack 412 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 421 to move proximally relative to the handle, and the outer tubular member 422 remain stationary relative to the handle, as described above. Thus and as noted above, during the second action, the inner shaft member 421 moves proximally relative to the handle 401 and the outer tubular member 422 is stationary relative to the handle.

FIGS. 95 and 96 provide, for the purpose of illustration and not limitation, portion of delivery system 1005. Elements that are similar to the previously described embodiment have been given like numbers. The delivery system 1005 can be configured to deliver an implant in a similar manner as described herein above.

The trigger 560 can include a slide 561 that can include an engagement surface 562 to be engaged by the user. The driving rack 512 can be fixedly coupled or releasably coupled to the slide 561. As an example and not by way of limitation, the driving rack 512 and the slide 561 can be a unitary member. The trigger 560 can be coupled to a spring, which can bias the trigger 560 toward the first position.

During operation, the user can deploy the trigger 560 from the first position to the second position (referred to herein as the “first action”). The trigger, and therefore the slide 561 and the driving rack 512, can move in a distal direction. The driving rack 512 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 521 to move distally relative to the handle, and the outer tubular member 522 to move proximally relative to the handle, as described above. Thus and as noted above, during the first action, the inner shaft member 521 can move distally relative to the handle 501 and the outer tubular member 522 can move proximally relative to the handle 501.

Upon return of the trigger 560 from the second position to the first position (herein referred to as the “second action”), the trigger 560, and therefore the slide 561 and the driving rack 512 can move in a proximal relative to the handle 501. The driving rack 512 can be functionally coupled to the actuation assembly, and can cause the inner shaft member 521 to move proximally relative to the handle, and the outer tubular member 522 remain stationary relative to the handle, as described above. Thus and as noted above, during the second action, the inner shaft member 521 moves proximally relative to the handle 501 and the outer tubular member 522 is stationary relative to the handle.

The embodiments described above can be formed of any suitable materials, for example, the handle and actuation assembly elements can be made from plastic, composites, or metal. As an example, and not by way of limitation, the gears, (for example, the sun gear shaft, planet carrier, planet gears, intermediate gear and ring gear), clutch drivers, shuttle frame, driving rack, and clutch release can be formed by silicon impregnated poly oxymethylene or acetal (e.g., DelRin® sold by DuPont). The ratchet rack can be made of TOPAS. The various pins and springs can be formed from plastic, metal (e.g., stainless steel or aluminum), or music wire. The plate can be formed from plastic or metal. The handle housing portion can be made from glass filled plastics or other plastic resins, for example ADS, polycarbonate, or an ADS polycarbonate blend. A rubber overmold can be used for grip and aesthetics, for example, on the trigger and the handle body. The strain relief can be a soft plastic, for example, polyethylene. The trigger and related elements can be formed by silicon impregnated poly oxymethylene or acetal (e.g., DelRin® sold by DuPont). The various pins and springs can be formed from plastic, metal (e.g., stainless steel or aluminum), or music wire. Spring dampers can be made of UNA, EPVM, Silicon, Eurothane, or Santoprene.

As disclosed herein, a delivery system can be provided with one or more of the described actuations assemblies, trigger assemblies or ratchet mechanisms. For example, a delivery system can be provided including a handle; a trigger operatively coupled to the handle; an actuation assembly operatively coupled to the trigger, the inner shaft member, and the outer tubular member, the actuation assembly having a planet carrier; at least one planet gear operatively coupled to the planet carrier; a sun gear shaft operatively engaged with the planet gear; a ring gear operatively engaged with the planet gear; a first clutch driver configured to limit the sun gear shaft to uni-directional rotational motion; and a second clutch driver configured to uni-directionally lock the sun gear shaft and the planet carrier; and a gear train functionally disposed between the trigger and the actuation assembly, the trigger having a trigger gear sector, a trigger pinion operatively meshed with the trigger gear sector, a slide pinion operatively coupled to the trigger pinion, and a slid rack disposed on a slide and operatively meshed with the trigger pinion. The actuation assembly is configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and further wherein the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position.

Additionally, and in accordance with the disclosed subject matter, a delivery system can be provided including a handle; a trigger operatively coupled to the handle; an actuation assembly including a planetary gear system; and a ratchet mechanism functionally coupled to the trigger. The actuation assembly is configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and further wherein the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position

Furthermore, and in accordance with the disclosed subject matter, a delivery system can be provided including a handle; a trigger operatively coupled to the handle; an actuation assembly operatively coupled to the trigger, the inner shaft member, and the outer tubular member, the actuation assembly having a planet carrier; at least one planet gear operatively coupled to the planet carrier; a sun gear shaft operatively engaged with the planet gear; a ring gear operatively engaged with the planet gear; a first clutch driver configured to limit the sun gear shaft to uni-directional rotational motion; and a second clutch driver configured to uni-directionally lock the sun gear shaft and the planet carrier; a gear train functionally disposed between the trigger and the actuation assembly, the trigger having a trigger gear sector, a trigger pinion operatively meshed with the trigger gear sector, a slide pinion operatively coupled to the trigger pinion, and a slid rack disposed on a slide and operatively meshed with the trigger pinion. The actuation assembly is configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and further wherein the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position.

While the disclosed subject matter is described herein in terms of certain preferred embodiments for purpose of illustration and not limitation, those skilled in the art will recognize that various modifications and improvements can be made to the disclosed subject matter without departing from the scope thereof. Moreover, although individual features of one embodiment of the disclosed subject matter can be discussed herein or shown in the drawings of one embodiment and not in other embodiments, it should be readily apparent that individual features of one embodiment can be combined with one or more features of another embodiment or features from a plurality of embodiments.

In addition to the specific embodiments claimed below, the disclosed subject matter is also directed to other embodiments having any other possible combination of the dependent features claimed below and those disclosed above. As such, the particular features presented in the dependent claims and disclosed above can be combined with each other in other possible combinations. Thus, the foregoing description of specific embodiments of the disclosed subject matter has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosed subject matter to those embodiments disclosed.

The following applications, which are filed on the same day as this application, are incorporated by reference in their entirety: U.S. patent application Ser. No. 14/932,848; U.S. patent application Ser. No. 14/932,875; U.S. patent application Ser. No. 14/932,862; U.S. patent application Ser. No. 14/932,884; U.S. patent application Ser. No. 14/932,795; U.S. patent application Ser. No. 14/932,805; U.S. patent application Ser. No. 14/932,830; PCT Application No. PCT/US2015/059070; PCT Application No. PCT/US2015/059074; and PCT Application No. PCT/US2015/059084.

Furthermore, it is recognized that the actuation assembly and delivery system as disclosed herein can be used in a method of delivering an implant. That is, for purpose of illustration, such method would include providing a delivery system as disclosed herein, positioning the distal end portion of the outer tubular member proximate a desired site, and deploying the delivery system to push the implant from the outer tubular member to the desired site.

It will be apparent to those skilled in the art that various modifications and variations can be made in the method and system of the disclosed subject matter without departing from the spirit or scope of the disclosed subject matter. Thus, it is intended that the disclosed subject matter include modifications and variations that are within the scope of the appended claims and their equivalents. 

1. A system for delivering an implant, the implant to be disposed within a distal end portion of an outer tubular member and positioned to be engaged by a distal end portion of an inner shaft member when the inner shaft member is moved distally relative to the outer tubular member, the inner shaft member being disposed within the outer tubular member and movable distally and proximally relative to the outer tubular member, comprising: a handle; a trigger operatively coupled to the handle; and an actuation assembly operatively coupled to the trigger, the inner shaft member, and the outer tubular member, wherein the actuation assembly is configured to displace the outer tubular member in the proximal direction a distance (d) relative to the handle and to separately move the inner shaft member distally a distance (x) relative to the handle upon deployment of the trigger from a first position to a second position, and further wherein the actuation assembly is configured to move the inner shaft member proximally a distance (y) relative to the handle with no displacement of the outer tubular member relative to the handle upon return of the trigger from the second position to the first position.
 2. The system claim 1, wherein the actuation assembly further includes: a planet carrier, at least one planet gear operatively coupled to the planet carrier, a sun gear shaft operatively engaged with the planet gear, a ring gear operatively engaged with the planet gear, a first clutch driver configured to limit the sun gear shaft to uni-directional rotational motion, and a second clutch driver configured to uni-directionally lock the sun gear shaft and the planet carrier.
 3. The system of claim 2, further comprising a gear train functionally disposed between the trigger and the actuation assembly, the gear train having: a trigger gear sector, a trigger pinion operatively meshed with the trigger gear sector, a slide pinion operatively coupled to the trigger pinion, and a slide rack disposed on a slide and operatively meshed with the slide pinion.
 4. The system of claim 3, wherein the second clutch driver is configured to uni-directionally lock the sun gear shaft and the planet carrier such that the sun gear shaft, planet carrier and the ring gear have a 1:1 ratio of rotation during deployment of the trigger from the first position to the second position.
 5. The system of claim 4, wherein the actuation assembly further comprises a clutch release operatively coupled to the second clutch driver and configured to prevent the second clutch driver from uni-directionally locking the sun gear shaft and the planet carrier when the clutch release is engaged by a stop.
 6. The system of claim 5, wherein the stop is disposed on the handle, and the stop engages the clutch release when the actuation assembly has moved proximally a distance (z) along the handle.
 7. The system of claim 5, wherein the clutch release comprises a saw-tooth portion and wherein the stop comprises a resilient abutment portion, and wherein the resilient abutment portion of the stop engages the saw-tooth portion of the clutch release when the actuation assembly has moved proximally a distance (z) along the handle.
 8. The system of claim 3, wherein the first clutch driver is configured to limit the sun gear shaft to uni-directional motion such that the sun gear shaft does not rotate during return of the trigger from the second position to the first position and the planetary gear rotates about the sun gear shaft.
 9. The system of claim 8, wherein the sun gear shaft is functionally coupled to the outer tubular member such that upon deployment of the trigger from the first position to the second position the sun gear shaft rotates and thereby causes the outer tubular member to move proximally.
 10. The system of claim 8, wherein the actuation assembly further comprises a shuttle frame having the planet carrier, the planet gear, the sun gear shaft, the ring gear, the first clutch driver and the second clutch driver disposed thereon.
 11. The system of claim 10, wherein the shuttle frame is fixedly coupled to the outer tubular member.
 12. The system of claim 11, wherein the sun gear shaft is functionally coupled to the handle such that upon deployment of the trigger from the first position to the second position the sun gear shaft rotates and the shuttle frame moves proximally a distance relative to the handle.
 13. The system of claim 12, wherein the actuation assembly further comprises an intermediate gear functionally disposed on the shuttle frame between the sun gear shaft and the handle, and operatively engaged with the sun gear shaft.
 14. The system of claim 10, wherein the actuation assembly further comprises a ratchet rack fixedly coupled to the inner shaft member and disposed on the shuttle frame.
 15. The system of claim 14, wherein the ratchet rack is operatively meshed with the ring gear.
 16. The system of claim 10, wherein the actuation assembly further comprises at least one pin configured to engage at least one pin track disposed within the handle to thereby guide the shuttle frame along the handle.
 17. The system of claim 16, wherein the at least one pin comprises a first pin disposed through an axis of an intermediate gear functionally disposed on the shuttle frame between the sun gear shaft and the handle, and operatively engaged with the sun gear shaft.
 18. The system of claim 17, wherein the at least one pin comprises a second and third pin, each of the second and third pin disposed through the shuttle frame.
 19. The system of claim 118, wherein the at least one pin comprises a fourth pin disposed through an axis of the sun gear shaft.
 20. The system of claim 10, wherein the actuation assembly further comprises a plate disposed on the shuttle frame.
 21. The system of claim 3, where the slide is coupled to a driving rack.
 22. The system of claim 21, wherein the driving rack is operatively engaged with the planet carrier and the driving rack is supported by the shuttle frame.
 23. The system of claim 21, wherein the driving rack is fixedly coupled to the slide.
 24. The system of claim 21, wherein the driving rack is detachably coupled to the slide.
 25. The system of claim 3, wherein the sun gear shaft comprises a sun gear portion, a sheath pinion, and a clutch engagement portion.
 26. The system of claim 3, wherein the planet carrier comprises a circumferential pinion, a clutch component, and at least one pin.
 27. The system of claim 3, wherein the ring gear comprises a circumferential pinion and a ring gear portion.
 28. The system of claim 3, wherein the first clutch driver and the second clutch driver each comprises a sun gear shaft engagement portion and a clutch portion. 